Targeted lipid particles and compositions and uses thereof

ABSTRACT

Provided herein are lipid particles containing a lipid bilayer enclosing a lumen or cavity, a henipavirus F protein molecule or biologically active portion thereof, and a targeted envelope protein containing a henipavirus envelope attachment glycoprotein G (G protein) or biologically active portion thereof and a binding domain, such as a single domain antibody (sdAb) variable domain. Also provided herein are targeted envelope proteins containing a G protein fused or linked to a binding domain, such as a sdAb variable domain, and polynucleotides encoding such proteins. Also provided are producer cells and compositions containing such targeted lipid particles and methods of making and using the targeted lipid particles.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. provisional application 63/003,168 entitled “Targeted Lipid Particles and compositions and Uses Thereof”, filed Mar. 31, 2020, and to U.S. provisional application 63/154,341, entitled “Targeted Lipid Particles and compositions and Uses Thereof”, filed Feb. 26, 2021, the contents of each of which are incorporated by reference in their entirety for all purposes.

INCORPORATION BY REFERENCE OF SEQUENCE LISTING

The present application is being filed along with a Sequence Listing in electronic format. The Sequence Listing is provided as a file entitled 186152003600SubSeqList.TXT, created Jun. 19, 2021, which is 2,076,399 bytes in size. The information in the electronic format of the Sequence Listing is incorporated by reference in its entirety

FIELD

The present disclosure relates to lipid particles containing a lipid bilayer enclosing a lumen or cavity, a henipavirus F protein molecule or biologically active portion thereof, and a targeted envelope protein containing a henipavirus envelope attachment glycoprotein G (G protein) or biologically active portion thereof and a binding domain, such as a single domain antibody (sdAb) variable domain. The present disclosure also provides a targeted envelope protein containing a G protein fused or linked to a binding domain, such as a sdAb variable domain, and polynucleotides encoding such proteins. Also disclosed are producer cells and compositions containing such targeted lipid particles and methods of making and using the targeted lipid particles.

BACKGROUND

Lipid particles, including virus-like particles and viral vectors, are commonly used for delivery of exogenous agents to cells. However, delivery of the lipid particles to certain target cells can be challenging. For lentivral vectors, the host range can be altered by pseudotyping with a heterologous envelope protein. Certain retargeted envelope proteins may not be sufficiently stable or expressed on the surface of the lipid particle. Improved lipid particles, including virus-like particles and viral vectors, for targeting desired cells are needed. The provided disclosure addresses this need.

SUMMARY

Provided herein is a targeted lipid particle which includes (a) a lipid bilayer enclosing a lumen, (b) a henipavirus F protein molecule or biologically active portion thereof; and (c) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) single domain antibody (sdAb) variable domain, wherein the sdAb variable domain is attached to the C-terminus of the G protein or the biologically active portion thereof, wherein the F protein molecule or the biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer. In some embodiments, the the single domain antibody is attached to the G protein via a linker. In some embodiments, the linker is a peptide linker.

Provided herein is a targeted lipid particle which includes (a) a lipid bilayer enclosing a lumen, (b) a henipavirus F protein molecule or biologically active portion thereof; and (c) a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or biologically active portion thereof attached to a single domain antibody (sdAb) variable domain via a peptide linker, wherein the single domain antibody binds to a cell surface molecule of a target cell, wherein the F protein molecule or biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer. In some embodiments, N-terminus of the F protein molecule or biologically active portion thereof is exposed on the outside of lipid bilayer. In some embodiments, the C-terminus of the G protein is exposed on the outside of the lipid bilayer.

In some embodiments, the single domain antibody binds a cell surface molecule present on a target cell. In some embodiments, the cell surface molecule is a protein, glycan, lipid or low molecular weight molecule. In some of any embodiments, the single domain antibody binds an antigen or portion thereof present on a target cell. In some embodiments, the antigen is the cell surface molecule or a portion of the cell surface molecule that contains an epitope recognized by the single domain antibody. In some of any embodiments, the target cell is selected from the group consisting of tumor-infiltrating lymphocytes, T cells, neoplastic or tumor cells, virus-infected cells, stem cells, central nervous system (CNS) cells, hematopoeietic stem cells (HSCs), liver cells or fully differentiated cells. In some embodiments, the target cell is selected from the group consisting of a CD3+ T cell, a CD4+ Tcell, a CD8+ T cell, a hepatocyte, a haematepoietic stem cell, a CD34+ haematepoietic stem cell, a CD105+ haematepoietic stem cell, a CD117+ haematepoietic stem cell, a CD105+ endothelial cell, a B cell, a CD20+ B cell, a CD19+ B cell, a cancer cell, a CD133+ cancer cell, an EpCAM+ cancer cell, a CD19+ cancer cell, a Her2/Neu+ cancer cell, a GluA2+ neuron, a GluA4+ neuron, a NKG2D+ natural killer cell, a SLC1A3+ astrocyte, a SLC7A10+ adipocyte, or a CD30+ lung epithelial cell. In some of any embodiments, the target cell is a hepatocyte. In some of any embodiments, the cell surface molecule or antigen is selected from the group consisting of ASGR1, ASGR2 and TM4SF5.

In some of any embodiments, the target cell is a T cell. In some of any embodiments, the cell surface molecule or antigen is CD8 or CD4.

In some of any embodiments, the cell surface molecule or antigen is LDL-R.

Provided herein are targeted lipid particles comprising (a) a lipid bilayer enclosing a lumen, (b) a henipavirus F protein molecule or biologically active portion thereof; and (c) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof, and wherein the binding domain binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, and TM4SF5, optionally human ASGR1, human ASGR2 and human ASGR2,

wherein the F protein molecule or the biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer.

Provided herein are targeted lipid particles comprising (a) a lipid bilayer enclosing a lumen, (b) a henipavirus F protein molecule or biologically active portion thereof; and (c) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof, and wherein the binding domain binds a cell surface molecule selected from the group consisting of CD8 and CD4, optionally human CD8 or human CD4, wherein the F protein molecule or the biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer.

Provided herein are targeted lipid particles comprising (a) a lipid bilayer enclosing a lumen, (b) a henipavirus F protein molecule or biologically active portion thereof; and (c) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof, and wherein the binding domain binds a cell surface molecule that is low density lipoprotein receptor (LDL-R), optionally human LDL-R, wherein the F protein molecule or the biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer.

In some of any embodiments, the lipid particle is a lentiviral vector. In some of any embodiments, the binding domain is attached to the G protein via a linker. In some of any embodiments, the linker is a peptide linker.

Provided herein is a lentiviral vector, comprising a binding domain that targets a cell surface molecule selected from the group consisting of ASGR1, ASGR2 and TM4SF5, optionally human ASGR1, human ASGR2 and human TM4SF5, wherein the lentiviral vector is pseudotyped with a retargeted viral fusion protein, said retargeted viral fusion protein comprising: (a) a henipavirus F protein molecule or biologically active portion thereof; and (b) a targeted envelope protein comprising the binding domain attached to a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof.

Provided herein is a lentiviral vector, comprising a binding domain that targets a cell surface molecule selected from the group consisting of CD8 and CD4, optionally human CD8 and human CD4, wherein the lentiviral vector is pseudotyped with a retargeted viral fusion protein, said retargeted viral fusion protein comprising: (a) a henipavirus F protein molecule or biologically active portion thereof; and (b) a targeted envelope protein comprising the binding domain attached to a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof.

Provided herein is a lentiviral vector, comprising a binding domain that targets low density lipoprotein receptor (LDL-R), optionally wherein the LDL-R is human LDL-R, wherein the lentiviral vector is pseudotyped with a retargeted viral fusion protein comprising (a) a henipavirus F protein molecule or biologically active portion thereof; and (b) a targeted envelope protein comprising the binding domain attached to a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof.

In some of any embodiments, the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof.

Provided herein is a lentiviral vector, comprising (a) a henipavirus F protein molecule or biologically active portion thereof; and (b) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof, and wherein the binding domain binds CD4; and (c) a cargo comprising nucleic acid encoding a chimeric antigen receptor (CAR), wherein the CAR comprises (i) an extracellular antigen binding domain that binds an extracellular antigen (e.g., CD19 or BCMA) and (ii) an intracellular signaling region a CD3zeta signaling domain and, optionally a 4-1BB or CD28 co-stimulatory signaling domain. In some embodiments, the extracellular antigen binding domain of the CAR is an scFv.

In some of any embodiments, the lentiviral vector is capable of delivering the nucleic acid encoding the CAR to T cells. In some embodiments the T cells are in vivo in a subject.

Provided herein is a lentiviral vector, comprising:(a) a henipavirus F protein molecule or biologically active portion thereof; and (b) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof, and wherein the binding domain binds ASGR1; wherein the lentiviral vector is capable of targeting to hepatocytes. In some of any embodiments, the lentiviral vector further comprises an exogenous agent for delivery to hepatocytes.

In some of any embodiments, the lentiviral vector is capable of delivering the exogenous agent to hepatocytes, optionally wherein the hepatocytes are in vivo in a subject.

In some of any embodiments, the binding domain is attached to the G protein via a linker. In some of any embodiments, the linker is a peptide linker. In some of any embodiments, the binding domain is a single domain antibody. In some of any embodiments, the binding domain is a single chain variable fragment (scFv).

In some of any embodiments, the peptide linker comprises up to 65 amino acids in length. In some of any embodiments, the peptide linker comprises up to 50 amino acids in length. In some of any embodiments, the peptide linker comprises from or from about 2 to 65 amino acids, 2 to 60 amino acids, 2 to 56 amino acids, 2 to 52 amino acids, 2 to 48 amino acids, 2 to 44 amino acids, 2 to 40 amino acids, 2 to 36 amino acids, 2 to 32 amino acids, 2 to 28 amino acids, 2 to 24 amino acids, 2 to 20 amino acids, 2 to 18 amino acids, 2 to 14 amino acids, 2 to 12 amino acids, 2 to 10 amino acids, 2 to 8 amino acids, 2 to 6 amino acids, 6 to 65 amino acids, 6 to 60 amino acids, 6 to 56 amino acids, 6 to 52 amino acids, 6 to 48 amino acids, 6 to 44 amino acids, 6 to 40 amino acids, 6 to 36 amino acids, 6 to 32 amino acids, 6 to 28 amino acids, 6 to 24 amino acids, 6 to 20 amino acids, 6 to 18 amino acids, 6 to 14 amino acids, 6 to 12 amino acids, 6 to 10 amino acids, 6 to 8 amino acids, 8 to 65 amino acids, 8 to 60 amino acids, 8 to 56 amino acids, 8 to 52 amino acids, 8 to 48 amino acids, 8 to 44 amino acids, 8 to 40 amino acids, 8 to 36 amino acids, 8 to 32 amino acids, 8 to 28 amino acids, 8 to 24 amino acids, 8 to 20 amino acids, 8 to 18 amino acids, 8 to 14 amino acids, 8 to 12 amino acids, 8 to 10 amino acids, 10 to 65 amino acids, 10 to 60 amino acids, 10 to 56 amino acids, 10 to 52 amino acids, 10 to 48 amino acids, 10 to 44 amino acids, 10 to 40 amino acids, 10 to 36 amino acids, 10 to 32 amino acids, 10 to 28 amino acids, 10 to 24 amino acids, 10 to 20 amino acids, 10 to 18 amino acids, 10 to 14 amino acids, 10 to 12 amino acids, 12 to 65 amino acids, 12 to 60 amino acids, 12 to 56 amino acids, 12 to 52 amino acids, 12 to 48 amino acids, 12 to 44 amino acids, 12 to 40 amino acids, 12 to 36 amino acids, 12 to 32 amino acids, 12 to 28 amino acids, 12 to 24 amino acids, 12 to 20 amino acids, 12 to 18 amino acids, 12 to 14 amino acids, 14 to 65 amino acids, 14 to 60 amino acids, 14 to 56 amino acids, 14 to 52 amino acids, 14 to 48 amino acids, 14 to 44 amino acids, 14 to 40 amino acids, 14 to 36 amino acids, 14 to 32 amino acids, 14 to 28 amino acids, 14 to 24 amino acids, 14 to 20 amino acids, 14 to 18 amino acids, 18 to 65 amino acids, 18 to 60 amino acids, 18 to 56 amino acids, 18 to 52 amino acids, 18 to 48 amino acids, 18 to 44 amino acids, 18 to 40 amino acids, 18 to 36 amino acids, 18 to 32 amino acids, 18 to 28 amino acids, 18 to 24 amino acids, 18 to 20 amino acids, 20 to 65 amino acids, 20 to 60 amino acids, 20 to 56 amino acids, 20 to 52 amino acids, 20 to 48 amino acids, 20 to 44 amino acids, 20 to 40 amino acids, 20 to 36 amino acids, 20 to 32 amino acids, 20 to 28 amino acids, 20 to 26 amino acids, 20 to 24 amino acids, 24 to 65 amino acids, 24 to 60 amino acids, 24 to 56 amino acids, 24 to 52 amino acids, 24 to 48 amino acids, 24 to 44 amino acids, 24 to 40 amino acids, 24 to 36 amino acids, 24 to 32 amino acids, 24 to 30 amino acids, 24 to 28 amino acids, 28 to 65 amino acids, 28 to 60 amino acids, 28 to 56 amino acids, 28 to 52 amino acids, 28 to 48 amino acids, 28 to 44 amino acids, 28 to 40 amino acids, 28 to 36 amino acids, 28 to 34 amino acids, 28 to 32 amino acids, 32 to 65 amino acids, 32 to 60 amino acids, 32 to 56 amino acids, 32 to 52 amino acids, 32 to 48 amino acids, 32 to 44 amino acids, 32 to 40 amino acids, 32 to 38 amino acids, 32 to 36 amino acids, 36 to 65 amino acids, 36 to 60 amino acids, 36 to 56 amino acids, 36 to 52 amino acids, 36 to 48 amino acids, 36 to 44 amino acids, 36 to 40 amino acids, 40 to 65 amino acids, 40 to 60 amino acids, 40 to 56 amino acids, 40 to 52 amino acids, 40 to 48 amino acids, 40 to 44 amino acids, 44 to 65 amino acids, 44 to 60 amino acids, 44 to 56 amino acids, 44 to 52 amino acids, 44 to 48 amino acids, 48 to 65 amino acids, 48 to 60 amino acids, 48 to 56 amino acids, 48 to 52 amino acids, 50 to 65 amino acids, 50 to 60 amino acids, 50 to 56 amino acids, 50 to 52 amino acids, 54 to 65 amino acids, 54 to 60 amino acids, 54 to 56 amino acids, 58 to 65 amino acids, 58 to 60 amino acids, or 60 to 65 amino acids. In some of any embodiments, peptide linker comprises a polypeptide that is 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64 or 65 amino acids in length. In some of any embodiments, wherein the peptide linker is a flexible linker that comprises GS, GGS, GGGGS (SEQ ID NO:43), GGGGGS (SEQ ID NO:41) or combinations thereof. In some of any embodiments, the peptide linker comprises (GGS)n, wherein n is 1 to 10. In some of any embodiments, the peptide linker comprises (GGGGS)n (SEQ ID NO: 42), wherein n is 1 to 10. In some of any embodiments, the peptide linker comprises (GGGGGS)n (SEQ ID NO:27), wherein n is 1 to 6.

In some of any embodiments, the G protein or the biologically active portion thereof is a wild-type Nipah virus G (NiV-G) protein or a Hendra virus G protein. In some of any embodiments, the G protein or the biologically active portion thereof is a wild-type NiV-G protein or a functionally active variant or biologically active portion thereof. In some of any embodiments, the mutant NiV-G protein or functionally active variant or biologically active portion thereof comprises an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44.

In some of any embodiments, the NiV-G protein is a biologically active portion that is truncated and lacks up to 40 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

In some of any embodiments, the NiV-G protein is a biologically active portion that is truncated at the N-terminus of wild-type NiV-G and has the sequence set forth in any of SEQ ID NOS: 10-15, 35-40 or 45-50 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NOs: 10-15, 35-40 or 45-50.

In some of any embodiments, the NiV-G protein is a biologically active portion that has a 5 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 10 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:10. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 35 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:35. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 45 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:45.

In some of any embodiments, the NiV-G protein is a biologically active portion that has a 10 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 36 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:36. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 11 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:11. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 46 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:46.

In some of any embodiments, the NiV-G protein or the biologically active portion has a 15 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 12 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:12. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 37 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:37. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 47 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:47.

In some of any embodiments, the NiV-G protein is a biologically active portion that has a 20 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 13 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:13. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 38 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:38. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 48 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:48.

In some of any embodiments, the NiV-G protein is a biologically active portion has a 25 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 14 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:14. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 39 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:39. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 49 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:49.

In some of any embodiments, the NiV-G protein is a biologically active portion has a 30 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 15 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:15. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 40 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:40.

In some of any embodiments, the NiV-G protein is a biologically active portion that has a 34 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 22 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:22. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 53 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:53.

In some of any embodiments, the G-protein, the biologically active portion thereof is a functionally active variant that is a mutant NiV-G protein that exhibits reduced binding to Ephrin B2 or Ephrin B3.

In some of any embodiments, the mutant NiV-G protein includes one or more amino acid substitutions corresponding to amino acid substitutions selected from the group consisting of E501A, W504A, Q530A and E533A with reference to numbering set forth in SEQ ID NO:28. In some of any embodiments, the mutant NiV-G protein includes the amino acid substitutions E501A, W504A, Q530A and E533A with reference to numbering set forth in SEQ ID NO:28.

In some of any embodiments, the mutant NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 16 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:16. In some of any embodiments, the mutant NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 51 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:51.

In some of any embodiments, the F protein or the biologically active portion thereof is a wild-type Nipah virus F (NiV-F) protein or a Hendra virus F protein or is a functionally active variant or biologically active portion thereof. In some of any embodiments, the F protein or the biologically active portion thereof is a wild-type NiV-F protein or a functionally active variant or a biologically active portion thereof. In some of any embodiments, the NiV-F-protein or the functionally active variant or biologically active portion thereof comprises the amino acid sequence set forth in SEQ ID NO: 2, or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 2.

In some of any embodiments, the NiV-F protein is a biologically active portion thereof that has a 20 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2).

In some of any embodiments, the NiV-F protein or the biologically active portion has the sequence set forth in SEQ ID NO:5 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 5.

In some of any embodiments, the NiV-F protein is a biologically active portion thereof that includes i) a 20 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2); and ii) a point mutation on an N-linked glycosylation site.

In some of any embodiments, the NiV-F protein or the biologically active portion has the sequence set forth in SEQ ID NO:7 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 7.

In some of any embodiments, the NiV-F protein is a biologically active portion thereof that has a 22 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2).

In some of any embodiments, NiV-F protein or the biologically active portion has the sequence set forth in SEQ ID NO:8 or an amino acid sequence that is encoded by a sequence of nucleotides encoding a sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 8.

In some of any embodiments, the NiV-F protein or the biologically active portion has the sequence set forth in SEQ ID NO:23 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 23. In some of any embodiments, the F-protein or the biologically active portion thereof comprises an F1 subunit or a fusogenic portion thereof.

In some of any embodiments, the F protein comprises the sequence set forth in SEQ ID NO:23 and the G protein comprises the sequence set forth in SEQ ID NO:16.

In some of any embodiments, the F protein consists or consists essentially of the sequence set forth in SEQ ID NO:23 and/or the G protein consists or consists essentially of the sequence set forth in SEQ ID NO:16.

In some of any embodiments, the F1 subunit is a proteolytically cleaved portion of the F0 precursor. In some of any embodiments, the F1 subunit comprises the sequence set forth in SEQ ID NO: 4, or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:4.

In some of any embodiments, the lipid bilayer is derived from a membrane of a host cell used for producing a retrovirus or retrovirus-like particle. In some of any embodiments, the host cell is selected from the group consisting of CHO cells, BHK cells, MDCK cells, C3H 10T1/2 cells, FLY cells, Psi-2 cells, BOSC 23 cells, PA317 cells, WEHI cells, COS cells, BSC 1 cells, BSC 40 cells, BMT 10 cells, VERO cells, W138 cells, MRCS cells, A549 cells, HT1080 cells, 293 cells, 293T cells, B-50 cells, 3T3 cells, NIH3T3 cells, HepG2 cells, Saos-2 cells, Huh7 cells, HeLa cells, W163 cells, 211 cells, and 211A cells. In some of any embodiments, the host cell comprises 293T cells. In some of any embodiments, the lipid bilayer is or comprises a viral envelope. In some of any embodiments, the retrovirus-like particle is replication defective.

In some of any embodiments, the targeted lipid particle comprises one or more viral components other than the F protein molecule and the G protein. In some of any embodiments, the one or more viral components are from a retrovirus. In some of any embodiments, the retrovirus is a lentivirus. In some of any embodiments, the one or more viral components comprise a viral packaging protein selected from one or more of Gag, Pol, Rev and Tat. In some of any embodiments, the one or more viral components comprises one or more of (e.g., all of) the following nucleic acid sequences: 5′ LTR (e.g., comprising U5 and lacking a functional U3 domain), Psi packaging element (Psi), Central polypurine tract (cPPT)/central termination sequence (CTS) (e.g. DNA flap), Poly A tail sequence, a posttranscriptional regulatory element (e.g. WPRE), a Rev response element (RRE), and 3′ LTR (e.g., comprising U5 and lacking a functional U3).

In some of any embodiments, the targeted lipid particle is a lentiviral vector.

In some of any embodiments, the targeted lipid particle or the lentiviral vector is replication defective.

In some of any embodiments, the targeted lipid particle or the lentiviral vector further comprises an exogenous agent. In some of any embodiments, the targeted lipid particle further comprises an exogenous agent. In some embodiments, the lentiviral vector further comprises an exogenous agent.

In some of any embodiments, the exogenous agent is present in the lumen. In some of any embodiments, the exogenous agent is a protein or a nucleic acid. In some embodiments, the nucleic acid is a DNA or RNA.

In some of any embodiments, the exogenous agent is a nucleic acid encoding a cargo for delivery to the target cell. In some of any embodiments, the exogenous agent encodes a therapeutic agent or a diagnostic agent.

In some of any embodiments, the exogenous agent encodes a membrane protein. In some embodiments, the membrane protein is an antigen receptor for targeting cells expressed by or associated with a disease or condition. In some embodiments, the membrane protein is a chimeric antigen receptor (CAR). In some embodiments, the CAR comprises (i) an extracellular antigen binding domain that binds an extracellular antigen (e.g., CD19 or BCMA), optionally wherein the extracellular antigen binding domain is an scFv, (ii) a transmembrane domain and (iii) an intracellular signaling region comprising a CD3zeta signaling domain and, optionally a co-stimulatory signaling domain, e.g., a 4-1BB or CD28 co-stimulatory signaling domain. In some embodiments, the target cell is a T cell. In some embodiments, the cell surface molecule on the target cell is CD4 or CD8. In some embodiments, the binding domain is an scFv that binds CD4 (e.g. human CD4). In some embodiments, the binding domain is a single domain antibody that binds CD4 (e.g. human CD4). In some embodiments, the binding domain is an scFv that binds CD8 (e.g. human CD8). In some embodiments, the binding domain is a single domain antibody that binds CD8 (e.g. human CD8).

In some of any embodiments, the exogenous agent is a nucleic acid comprising a payload gene for correcting a genetic deficiency, optionally a genetic deficiency in the target cell. In some embodiments, the genetic deficiency is associated with a liver cell or a hepatocyte. In some embodiments, the target cell is a hepatocyte. In some embodiments, the cell surface molecule is a molecule selected from the group consisting of ASGR1, ASGR2 and TM4SF5. In some embodiments, the binding domain is an scFv that binds ASGR1 (e.g. human ASGR1). In some embodiments, the binding domain is a single domain antibody that binds ASGR1 (e.g. human ASGR1). In some embodiments, the binding domain is an scFv that binds ASGR2 (e.g. human ASGR2). In some embodiments, the binding domain is a single domain antibody that binds ASGR2 (e.g. human ASGR2). In some embodiment, the binding domain is a scFv that binds TM4SF5 (e.g. human TM4SF5). In some embodiments, the binding domain is a single domain antibody that binds TM4SF5 (e.g. human TM4SF5).

In some of any embodiments, the single domain antibody binds a cell surface molecule present on a target cell. In some of any embodiments, the cell surface molecule is a protein, glycan, lipid or low molecular weight molecule. In some of any embodiments, the target cell is selected from the group consisting of tumor-infiltrating lymphocytes, T cells, neoplastic or tumor cells, virus-infected cells, stem cells, central nervous system (CNS) cells, hematopoeietic stem cells (HSCs), liver cells or fully differentiated cells. In some of any embodiments, the target cell is selected from the group consisting of a CD3+ T cell, a CD4+ Tcell, a CD8+ T cell, a hepatocyte, a haematepoietic stem cell, a CD34+ haematepoietic stem cell, a CD105+ haematepoietic stem cell, a CD117+ haematepoietic stem cell, a CD105+ endothelial cell, a B cell, a CD20+ B cell, a CD19+ B cell, a cancer cell, a CD133+ cancer cell, an EpCAM+ cancer cell, a CD19+ cancer cell, a Her2/Neu+ cancer cell, a GluA2+ neuron, a GluA4+ neuron, a NKG2D+ natural killer cell, a SLC1A3+ astrocyte, a SLC7A10+ adipocyte, or a CD30+ lung epithelial cell.

In some of any embodiments, the single domain antibody binds an antigen or portion thereof present on a target cell. In some of any embodiments, the cell surface molecule or antigen is selected from the group consisting of ASGR1, ASGR2 and TM4SF5. In some embodiments, the antigen or portion thereof is human ASGR1. In some embodiments, the antigen or portion thereof is human ASGR2. In some embodiments, the antigen or portion thereof is human TM4SF5.

Provided herein is a polynucleotide comprising a nucleic acid sequence encoding (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain that binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, and TM4SF5. In some embodiments, the cell surface molecule is human ASGR1. In some embodiments, the cell surface molecule is human ASGR2. In some embodiments, the cell surface molecule is human TM4SF5. In some of any embodiments, the cell surface molecule or antigen is CD8 or CD4.

Provided herein is a nucleic acid sequence encoding (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain that binds a cell surface molecule selected from the group consisting of CD4 and CD8. In some embodiments, the cell surface molecule is human CD4. In some embodiments, the cell surface molecule is human CD8. In some embodiments, the cell surface molecule or antigen is low density lipoprotein receptor (LDL-R). In some embodiments, the cell surface molecule or antigen is human LDL-R.

Provided herein is a polynucleotide comprising a nucleic acid sequence encoding (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain that binds low density lipoprotein receptor (LDL-R). In some embodiments, the binding domain binds human LDL-R. In some of any embodiments, the binding domain is a single domain antibody (sdAb). In some of any embodiments, the binding domain is a single chain variable fragment (scFv).

Provided herein is a polynucleotide comprising a nucleic acid sequence encoding (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a single domain antibody (sdAb) variable domain, wherein the sdAb variable domain is attached to the C-terminus of the G protein or the biologically active portion thereof. In some of any embodiments, the polynucleotide further comprises (iii) a nucleic acid sequence encoding a henipavirus F protein molecule or a biologically active portion thereof.

In some embodiments, the nucleic acid sequence is a first nucleic acid sequence and the polynucleotide further comprise a second nucleic acid sequence encoding a henipavirus F protein molecule or a biologically active portion thereof. In some embodiments, the polynucleotide comprise an IRES or a sequence encoding a linking peptide between the first and second nucleic acid sequence. In some embodiments, the linking peptide is a self-cleaving peptide or a peptide that causes ribosome skipping, optionally a T2A peptide.

In some of any embodiments, the polynucleotide includes at least one promoter that is operatively linked to control expression of the nucleic acid. In some of any embodiments, the promoter is operatively linked to control expression of the first nucleic acid sequence and the second nucleic acid sequence. In some of any embodiments, the promoter is a constitutive promoter. In some of any embodiments, the promoter is an inducible promoter.

In some of any embodiments, the sdAb variable domain is attached to the G protein via an encoded peptide linker. In some embodiments, the binding domain is attached to the G protein via an encoded peptide linker. In some of any embodiments, the encoded peptide linker comprises up to 25 amino acids in length. In some of any embodiments, the encoded peptide linker comprises up to 65 amino acids in length In some of any embodiments, the encoded peptide linker comprises from or from about 2 to 65 amino acids, 2 to 60 amino acids, 2 to 56 amino acids, 2 to 52 amino acids, 2 to 48 amino acids, 2 to 44 amino acids, 2 to 40 amino acids, 2 to 36 amino acids, 2 to 32 amino acids, 2 to 28 amino acids, 2 to 24 amino acids, 2 to 20 amino acids, 2 to 18 amino acids, 2 to 14 amino acids, 2 to 12 amino acids, 2 to 10 amino acids, 2 to 8 amino acids, 2 to 6 amino acids, 6 to 65 amino acids, 6 to 60 amino acids, 6 to 56 amino acids, 6 to 52 amino acids, 6 to 48 amino acids, 6 to 44 amino acids, 6 to 40 amino acids, 6 to 36 amino acids, 6 to 32 amino acids, 6 to 28 amino acids, 6 to 24 amino acids, 6 to 20 amino acids, 6 to 18 amino acids, 6 to 14 amino acids, 6 to 12 amino acids, 6 to 10 amino acids, 6 to 8 amino acids, 8 to 65 amino acids, 8 to 60 amino acids, 8 to 56 amino acids, 8 to 52 amino acids, 8 to 48 amino acids, 8 to 44 amino acids, 8 to 40 amino acids, 8 to 36 amino acids, 8 to 32 amino acids, 8 to 28 amino acids, 8 to 24 amino acids, 8 to 20 amino acids, 8 to 18 amino acids, 8 to 14 amino acids, 8 to 12 amino acids, 8 to 10 amino acids, 10 to 65 amino acids, 10 to 60 amino acids, 10 to 56 amino acids, 10 to 52 amino acids, 10 to 48 amino acids, 10 to 44 amino acids, 10 to 40 amino acids, 10 to 36 amino acids, 10 to 32 amino acids, 10 to 28 amino acids, 10 to 24 amino acids, 10 to 20 amino acids, 10 to 18 amino acids, 10 to 14 amino acids, 10 to 12 amino acids, 12 to 65 amino acids, 12 to 60 amino acids, 12 to 56 amino acids, 12 to 52 amino acids, 12 to 48 amino acids, 12 to 44 amino acids, 12 to 40 amino acids, 12 to 36 amino acids, 12 to 32 amino acids, 12 to 28 amino acids, 12 to 24 amino acids, 12 to 20 amino acids, 12 to 18 amino acids, 12 to 14 amino acids, 14 to 65 amino acids, 14 to 60 amino acids, 14 to 56 amino acids, 14 to 52 amino acids, 14 to 48 amino acids, 14 to 44 amino acids, 14 to 40 amino acids, 14 to 36 amino acids, 14 to 32 amino acids, 14 to 28 amino acids, 14 to 24 amino acids, 14 to 20 amino acids, 14 to 18 amino acids, 18 to 65 amino acids, 18 to 60 amino acids, 18 to 56 amino acids, 18 to 52 amino acids, 18 to 48 amino acids, 18 to 44 amino acids, 18 to 40 amino acids, 18 to 36 amino acids, 18 to 32 amino acids, 18 to 28 amino acids, 18 to 24 amino acids, 18 to 20 amino acids, 20 to 65 amino acids, 20 to 60 amino acids, 20 to 56 amino acids, 20 to 52 amino acids, 20 to 48 amino acids, 20 to 44 amino acids, 20 to 40 amino acids, 20 to 36 amino acids, 20 to 32 amino acids, 20 to 28 amino acids, 20 to 26 amino acids, 20 to 24 amino acids, 24 to 65 amino acids, 24 to 60 amino acids, 24 to 56 amino acids, 24 to 52 amino acids, 24 to 48 amino acids, 24 to 44 amino acids, 24 to 40 amino acids, 24 to 36 amino acids, 24 to 32 amino acids, 24 to 30 amino acids, 24 to 28 amino acids, 28 to 65 amino acids, 28 to 60 amino acids, 28 to 56 amino acids, 28 to 52 amino acids, 28 to 48 amino acids, 28 to 44 amino acids, 28 to 40 amino acids, 28 to 36 amino acids, 28 to 34 amino acids, 28 to 32 amino acids, 32 to 65 amino acids, 32 to 60 amino acids, 32 to 56 amino acids, 32 to 52 amino acids, 32 to 48 amino acids, 32 to 44 amino acids, 32 to 40 amino acids, 32 to 38 amino acids, 32 to 36 amino acids, 36 to 65 amino acids, 36 to 60 amino acids, 36 to 56 amino acids, 36 to 52 amino acids, 36 to 48 amino acids, 36 to 44 amino acids, 36 to 40 amino acids, 40 to 65 amino acids, 40 to 60 amino acids, 40 to 56 amino acids, 40 to 52 amino acids, 40 to 48 amino acids, 40 to 44 amino acids, 44 to 65 amino acids, 44 to 60 amino acids, 44 to 56 amino acids, 44 to 52 amino acids, 44 to 48 amino acids, 48 to 65 amino acids, 48 to 60 amino acids, 48 to 56 amino acids, 48 to 52 amino acids, 50 to 65 amino acids, 50 to 60 amino acids, 50 to 56 amino acids, 50 to 52 amino acids, 54 to 65 amino acids, 54 to 60 amino acids, 54 to 56 amino acids, 58 to 65 amino acids, 58 to 60 amino acids, or 60 to 65 amino acids.

In some of any embodiments, the encoded peptide linker comprises a polypeptide that is 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64 or 65 amino acids in length. In some of any embodiments, the encoded peptide linker comprises GS, GGS, GGGGS (SEQ ID NO:43), GGGGGS (SEQ ID NO:41) and combinations thereof. In some of any embodiments, the encoded peptide linker comprises (GGS)n, wherein n is 1 to 10. In some of any embodiments, the encoded peptide linker comprises (GGGGS)n (SEQ ID NO:42), wherein n is 1 to 10. In some of any embodiments, the encoded peptide linker comprises (GGGGGS)n (SEQ ID NO:27), wherein n is 1 to 4. In some of any embodiments, the sequence encoding the G protein is a wild-type Nipah virus G (NiV-G) protein or a Hendra virus G protein or is a functionally active variant or a biologically active portion thereof. In some embodiments, the variant is a variant thereof that exhibits reduced binding for the native binding partner. In some of any embodiments, the nucleic acid sequence encoding the G protein is a wild-type Nipah virus G (NiV-G) protein or a Hendra virus G protein or is a variant thereof that exhibits reduced binding for the native binding partner. In some embodiments, the encoded G protein is a wild-type NiV-G protein or a functionally active variant or a biologically active portion thereof. In some of any embodiments, the nucleic acid sequence encoding the G protein is a wild-type NiV-G protein. In some of any embodiments, the nucleic acid sequence encoding the G-protein is a mutant NiV-G protein that exhibits reduced binding to Ephrin B2 or Ephrin B3.

In some of any embodiments, the NiV-G protein or functionally active variant or biologically active portion thereof comprises the amino acid sequence set forth in SEQ ID NO:9, SEQ ID NO: 28 or SEQ ID NO: 44 or comprises an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44. In some of any embodiments, the NiV-G protein is a biologically active portion that is truncated and lacks up to 40 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein is a biologically active portion that is truncated at the N-terminus of wild-type NiV-G and comprises the sequence set forth in any of SEQ ID NOS: 10-15, 35-40 or 45-50 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NOs: 10-15, 35-40 or 45-50.

In some of any embodiments, the NiV-G protein is a biologically active portion that comprises a 5 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 10 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:10. In some of any embodiments, NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 35 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:35. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 45 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:45.

In some of any embodiments, NiV-G protein is a biologically active portion that comprises a 10 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the mutant NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 11 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:11. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 36 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:36. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 46 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:46.

In some of any embodiments, the is a biologically active portion that NiV-G protein comprises a 15 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 12 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:12. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 37 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:37. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 47 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:47.

In some of any embodiments, the NiV-G protein is a biologically active portion that comprises a 20 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 13 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:13. In some of any embodiments, NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 38 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:38. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 48 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:48.

In some of any embodiments, the NiV-G protein is a biologically active portion that comprises a 25 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 14 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:14. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 39 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:39. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 49 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:49.

In some of any embodiments, the NiV-G protein is a biologically active portion that comprises a 30 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 15 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:15. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 40 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:40. In some of any embodiments, the NiV-G protein or the biologically active portion comprises the amino acid sequence set forth in SEQ ID NO: 50 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 50.

In some of any embodiments, the NiV-G protein is a biologically active portion that has a 34 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44). In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 22 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:22. In some of any embodiments, the NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 53 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:53.

In some of any embodiments, the G-protein is a mutant NiV-G protein that exhibits reduced binding to Ephrin B2 or Ephrin B3. In some of any embodiments, the mutant NiV-G protein comprises: one or more amino acid substitutions corresponding to amino acid substitutions selected from the group consisting of E501A, W504A, Q530A and E533A with reference to numbering set forth in SEQ ID NO:28. In some of any embodiments, the mutant NiV-G protein comprises amino acid substitutions E501A, W504A, Q530A and E533A with reference to numbering set forth in SEQ ID NO:28.

In some of any embodiments, the mutant NiV-G protein comprises: i) a truncation at or near the N-terminus; and ii) point mutations selected from the group consisting of E501A, W504A, Q530A and E533A. In some of any embodiments, the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 16 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:16. In some of any embodiments, the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 51 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:51.

In some of any embodiments, the F protein or the biologically active portion thereof is a wild-type Nipah virus F (NiV-F) protein or a Hendra virus F protein or is a functionally active variant or biologically active portion thereof. In some of any embodiments, the F protein or the biologically active portion thereof is a wild-type NiV-F protein or a functionally active variant or a biologically active portion thereof. In some of any embodiments, the NiV-F-protein or the functionally active variant or biologically active portion thereof comprises the amino acid sequence set forth in SEQ ID NO: 2, or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 2.

In some of any embodiments, the NiV-F protein is a is a biologically active portion thereof that has a 20 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2). In some of any embodiments, the NiV-F protein or the biologically active portion has the sequence set forth in SEQ ID NO:5 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 5. In some of any embodiments, the NiV-F protein is a biologically active portion thereof that comprises i) a 20 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2); and ii) a point mutation on an N-linked glycosylation site.

In some of any embodiments, the NiV-F protein or the biologically active portion has the sequence set forth in SEQ ID NO:7 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 7.

In some of any embodiments, the NiV-F protein is a biologically active portion thereof that has a 22 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2). In some of any embodiments, the NiV-F protein or the biologically active portion has the sequence set forth in SEQ ID NO:8 or an amino acid sequence that is encoded by a sequence of nucleotides encoding a sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 8.

In some of any embodiments, the NiV-F protein has the sequence set forth in SEQ ID NO:23 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 23. In some of any embodiments, the F protein comprises the sequence set forth in SEQ ID NO:23 and the G protein comprises the sequence set forth in SEQ ID NO:16. In some of any embodiments, the F protein consists or consists essentially of the sequence set forth in SEQ ID NO:23 and the G protein consists or consists essentially of the sequence set forth in SEQ ID NO:16.

Provided herein is a vector, comprising the polynucleotide of any of the embodiments described herein. In some of any embodiments, the vector is a mammalian vector, viral vector or artificial chromosome, optionally wherein the artificial chromosome is a bacterial artificial chromosome (BAC).

Provided herein is a plasmid, comprising the polynucleotide of any of the embodiments described herein. In some of any embodiments, the plasmid further comprises one or more nucleic acids encoding proteins for lentivirus production.

Provided herein is a cell comprising the polynucleotide of any of embodiments described herein or the vector of any of the embodiments described herein, or the plasmid of any of the embodiments described herein.

Provided herein is a method of making a targeted lipid particle comprising a henipavirus F protein molecule or biologically active portion thereof and a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain, the method comprising a) providing a cell that comprises a nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and a nucleic acid encoding a targeted envelope protein, the targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain; b) culturing the cell under conditions that allow for production of a targeted lipid particle, and c) separating, enriching, or purifying the targeted lipid particle from the cell, thereby making the targeted lipid particle.

Provided herein is a method of making a pseudotyped lentiviral vector, the method comprising a) providing a producer cell that comprises a lentiviral viral nucleic acid(s), a nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof, and a nucleic acid encoding a targeted envelope protein, said targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody; b) culturing the cell under conditions that allow for production of the lentiviral vector, and c) separating, enriching, or purifying the lentiviral vector from the cell, thereby making the pseudotyped lentiviral vector.

In some of any embodiments, the single domain antibody binds a cell surface molecule present on a target cell. In some of any embodiments, the cell surface molecule is a protein, glycan, lipid or low molecular weight molecule. In some of any embodiments, the target cell is selected from the group consisting of tumor-infiltrating lymphocytes, T cells, neoplastic or tumor cells, virus-infected cells, stem cells, central nervous system (CNS) cells, hematopoeietic stem cells (HSCs), liver cells or fully differentiated cells. In some of any embodiments, the target cell is selected from the group consisting of a CD3+ T cell, a CD4+ Tcell, a CD8+ T cell, a hepatocyte, a haematepoietic stem cell, a CD34+ haematepoietic stem cell, a CD105+ haematepoietic stem cell, a CD117+ haematepoietic stem cell, a CD105+ endothelial cell, a B cell, a CD20+ B cell, a CD19+ B cell, a cancer cell, a CD133+ cancer cell, an EpCAM+ cancer cell, a CD19+ cancer cell, a Her2/Neu+ cancer cell, a GluA2+ neuron, a GluA4+ neuron, a NKG2D+ natural killer cell, a SLC1A3+ astrocyte, a SLC7A10+ adipocyte, or a CD30+ lung epithelial cell. In some of any embodiments, the single domain antibody binds an antigen or portion thereof present on a target cell.

Provided herein is a method of making a targeted lipid particle comprising a henipavirus F protein molecule or biologically active portion thereof and a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a binding domain, the method comprising a) providing a cell that comprises a nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and a nucleic acid encoding a targeted envelope protein, the targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and binding domain, wherein the binding domain (i) binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, and TM4SF5, optionally human ASGR1, human ASGR2 and human ASGR2; (ii) binds a cell surface molecule selected from the group consisting of CD4 or CD8, optionally human CD4 or human CD8; or (iii) binds a cell surface molecule that is low density lipoprotein receptor (LDL-R), optionally human LDL-R; b) culturing the cell under conditions that allow for production of a targeted lipid particle, and c) separating, enriching, or purifying the targeted lipid particle from the cell, thereby making the targeted lipid particle.

Provided herein is a method of making a pseudotyped lentiviral vector, the method comprising a) providing a producer cell that comprises a lentiviral viral nucleic acid(s), a nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof, and a nucleic acid encoding a targeted envelope protein, said targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and binding domain, wherein the binding domain: (i) binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, and TM4SF5, optionally human ASGR1, human ASGR2 and human ASGR2; (ii) binds a cell surface molecule selected from the group consisting of CD4 or CD8, optionally human CD4 or human CD8; or (iii) binds a cell surface molecule that is low density lipoprotein receptor (LDL-R), optionally human LDL-R; b) culturing the producer cell under conditions that allow for production of a lentiviral vector, and c) separating, enriching, or purifying the lentiviral vector from the cell, thereby making the pseudotyped lentiviral vector.

In some of any embodiments, the binding domain is a single domain antibody. In some of any embodiments, the binding domain is a single chain variable fragment (scFv). In some of any embodiments, the cell surface molecule is selected from the group consisting of ASGR1, ASGR2 and TM4SF5. In some of any embodiments, the cell surface molecule is CD8 or CD4, In some of any embodiments, the cell surface molecule is LDL-R.

Provided herein is a method of making a targeted lipid particle comprising a henipavirus F protein molecule or biologically active portion thereof and a targeted envelope protein comprising a) providing a cell that comprises the polynucleotide of any of the embodiments provided herein the vector of any of the embodiments described herein, or the plasmid of any of the embodiments described herein; b) culturing the cell under conditions that allow for production of a targeted lipid particle, and c) separating, enriching, or purifying the targeted lipid particle particle from the cell, thereby making the targeted lipid particle.

Provided herein is a method of making a pseudotyped lentiviral vector, comprising: a) providing a producer cell that comprises a lentiviral viral nucleic acid(s), and the polynucleotide of any of the embodiments listed herein or the vector of any of the embodiments listed herein b) culturing the cell under conditions that allow for production of the lentiviral vector, and c) separating, enriching, or purifying the lentiviral vector from the cell, thereby making the pseudotyped lentiviral vector. In some of any embodiments, prior to step (b) the method further comprises providing the cell a polynucleotide encoding a henipavirus F protein molecule or biologically active portion thereof.

In some of any embodiments, the cell is a mammalian cell.

In some of any embodiments, the cell is a producer cell comprising viral nucleic acid. In some of any embodiments, the viral nucleic acid is a retroviral nucleic acid or lentiviral nucleic acid and the targeted lipid particle is a viral particle or a viral-like particle. In some of any embodiments, the viral particle or a viral-like particle is a retroviral particle or a retroviral-like particle. In some embodiments, the viral particle or a viral-like particle is a lentiviral particle or lentiviral-like particle.

In some of any embodiments, the viral nucleic acid(s) lacks one or more genes involved in viral replication. In some of any embodiments, the viral nucleic acid comprises a nucleic acid encoding a viral packaging protein selected from one or more of Gag, Pol, Rev and Tat. In some of any embodiments, the viral nucleic acid comprises:one or more of (e.g., all of) the following nucleic acid sequences: 5′ LTR (e.g., comprising U5 and lacking a functional U3 domain), Psi packaging element (Psi), Central polypurine tract (cPPT)/central termination sequence (CTS) (e.g. DNA flap), Poly A tail sequence, a posttranscriptional regulatory element (e.g. WPRE), a Rev response element (RRE), and 3′ LTR (e.g., comprising U5 and lacking a functional U3).

Provided herein is a producer cell comprising the polynucleotide of any of the embodiments listed herein or the vector of any of the embodiments listed herein, or the plasmid of any of the embodiments described herein.

In some of any embodiments, the producer cell further comprises a nucleic acid encoding a henipavirus F protein or a biologically active portion thereof.

In some of any embodiments, the cell further comprises a viral nucleic acid. In some of any embodiments, the viral nucleic acid is a lentiviral nucleic acid. Provided herein is a producer cell comprising (i) a viral nucleic acid(s) and (ii) nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and (iii) a nucleic acid encoding a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain, optionally wherein the viral nucleic acid(s) are lentiviral nucleic acids. In some of any embodiments the single domain antibody binds a cell surface molecule present on a target cell. In some of any embodiments the cell surface molecule is a protein, glycan, lipid or low molecular weight molecule.

In some of any embodiments the target cell is selected from the group consisting of tumor-infiltrating lymphocytes, T cells, neoplastic or tumor cells, virus-infected cells, stem cells, central nervous system (CNS) cells, hematopoeietic stem cells (HSCs), liver cells or fully differentiated cells. In some of any embodiments the target cell is selected from the group consisting of a CD3+ T cell, a CD4+ Tcell, a CD8+ T cell, a hepatocyte, a haematepoietic stem cell, a CD34+ haematepoietic stem cell, a CD105+ haematepoietic stem cell, a CD117+ haematepoietic stem cell, a CD105+ endothelial cell, a B cell, a CD20+ B cell, a CD19+ B cell, a cancer cell, a CD133+ cancer cell, an EpCAM+ cancer cell, a CD19+ cancer cell, a Her2/Neu+ cancer cell, a GluA2+ neuron, a GluA4+ neuron, a NKG2D+ natural killer cell, a SLC1A3+ astrocyte, a SLC7A10+ adipocyte, or a CD30+ lung epithelial cell. In some of any embodiments the single domain antibody binds an antigen or portion thereof present on a target cell.

Provided herein is a producer cell comprising (i) a viral nucleic acid(s) and (ii) nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and (iii) a nucleic acid encoding a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and binding domain, wherein the binding domain (i) binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, and TM4SF5, optionally human ASGR1, human ASGR2 and human ASGR2; (ii) binds a cell surface molecule selected from the group consisting of CD4 or CD8, optionally human CD4 or human CD8; or (iii) binds a cell surface molecule that is low density lipoprotein receptor (LDL-R), optionally human LDL-R. In some of any embodiments the viral nucleic acid(s) are lentiviral nucleic acid.

In some of any embodiments the cell surface molecule or antigen is selected from the group consisting of ASGR1, ASGR2 and TM4SF5. In some of any embodiments, the cell surface molecule or antigen is CD8 or CD4. In some of any embodiments, the cell surface molecule or antigen is LDL-R.

In some of any embodiments, the viral nucleic acid(s) lacks one or more genes involved in viral replication. In some of any embodiments, the viral nucleic acid comprises a nucleic acid encoding a viral packaging protein selected from one or more of Gag, Pol, Rev and Tat.

In some of any embodiments, the viral nucleic acid comprises one or more of (e.g., all of) the following nucleic acid sequences: 5′ LTR (e.g., comprising U5 and lacking a functional U3 domain), Psi packaging element (Psi), Central polypurine tract (cPPT)/central termination sequence (CTS) (e.g. DNA flap), Poly A tail sequence, a posttranscriptional regulatory element (e.g. WPRE), a Rev response element (RRE), and 3′ LTR (e.g., comprising U5 and lacking a functional U3).

In some of any embodiments, the henipavirus F protein molecule or biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 2; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:2. In some of any embodiments, the henipavirus F protein molecule or biologically active portion thereof comprises (i) the sequence set forth in SEQ ID NO: 5; (ii) an amino acid sequence having at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:5.

In some of any embodiments, the henipavirus F protein molecule or biologically active portion thereof comprises (i) the sequence set forth in SEQ ID NO: 7; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:7. In some of any embodiments, the henipavirus F protein molecule or biologically active portion thereof comprises (i) a sequence encoding by a nucleotide sequence encoding the sequence set forth in SEQ ID NO: 8; (ii) a amino acid sequence encoded by a nucleotide sequence encoding a sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:8.

In some of any embodiments, the henipavirus F protein molecule or biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 23; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:23.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 10; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:10.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 35; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:35.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 45; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:45.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 11; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:11.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 36; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:36.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 46; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:46.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 12; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:12.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 37; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:37.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 47; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:47.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises (i) the sequence set forth in SEQ ID NO: 13; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:13.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 38; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:38.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 48; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:48.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises (i) the sequence set forth in SEQ ID NO: 14; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:14.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 39; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:39.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 49; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:49.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises (i) the sequence set forth in SEQ ID NO: 15; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:15.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 40; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:40.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises: (i) the sequence set forth in SEQ ID NO: 50; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:50.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises (i) the sequence set forth in SEQ ID NO: 16; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:16.

In some of any embodiments, the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises (i) the sequence set forth in SEQ ID NO: 51; (ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:51.

In some aspects of the provided embodiments, the targeted lipid particle has greater expression of the targeted envelope protein compared to a reference lipid particle that has incorporated into a similar lipid bilayer the same envelope protein but that is fused to an alternative targeting moiety, optionally wherein the alternative targeting moiety is a single chain variable fragment (scFv). In some of any embodiments, the expression is increased by at or greater than 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 125%, 150%, 200%, 300%, 400%, 500% or more. In some embodiments, the expression is increased by at or greater than 1.5-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold, 15-fold, 20-fold, 30-fold or more, preferably at or about or greater than 10-fold or more. In some of any embodiments, the titer in target cells following transduction is at or greater than 1×10⁶ transduction units (TU)/mL, at or greater than 2×10⁶ TU/mL, at or greater than 3×10⁶ TU/mL, at or greater than 4×10⁶ TU/mL, at or greater than 5×10⁶ TU/mL, at or greater than 6×10⁶ TU/mL, at or greater than 7×10⁶ TU/mL, at or greater than 8×10⁶ TU/mL, at or greater than 9×10⁶ TU/mL, or at or greater than 1×10⁷ TU/mL. Also provided herein is a composition wherein among the population of lipid particles, greater than at or about 50%, greater than at or about 55%, greater than at or about 60%, greater than at or about 65%, greater than at or about 70%, or greater than at or about 75% are surface positive for the targeted envelope protein. In some of any embodiments, the targeted envelope protein is present on the surface of the targeted lipid particle at a density of at least about (0.001, 0.002, 0.005, 0.01, 0.02, 0.05, 0.1, 0.2 or 0.5) targeted envelope proteins/nm².

Provided herein is a viral vector particle or viral-like particle produced from the producer cell of any of the embodiments provided herein.

Provided herein is a composition comprising a plurality of targeted lipid particles of any of the embodiments provided herein. In some embodiments, the composition further includes a pharmaceutically acceptable carrier. In some of any embodiments, the targeted lipid particles comprise an average diameter of less than 1 In some of any embodiments, the composition further includes a targeted envelope protein present on the surface of the targeted lipid particles at an average density of at least about (0.001, 0.002, 0.005, 0.01, 0.02, 0.05, 0.1, 0.2 or 0.5) targeted envelope proteins/nm².

Provided herein is a producer cell containing greater membrane (e.g., plasma membrane) expression of the targeted envelope protein compared to a reference producer cell that has incorporated into its membrane (e.g. plasma membrane) the same envelope protein but that is fused to an alternative targeting moiety, optionally wherein the alternative targeting moiety is a single chain variable fragment (scFv). In some embodiments, the expression is increased by at or greater than 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 125%, 150%, 200%, 300%, 400%, 500% or more. In some embodiments, the expression is increased by at or greater than 1.5-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold, 15-fold, 20-fold, 30-fold or more, preferably at or about or greater than 10-fold or more. In some embodiments, the producer cell has the expression of the targeted envelope protein on a membrane (e.g., plasma membrane) of the producer cell is at least 20 proteins (e.g., at least 50, 100, 200, 500, 1000, 2000, 5000, or 10,000 proteins) per square micron. In some of any embodiments, the targeted envelope protein comprises at least 0.1% (e.g., at least 0.2%, 0.5%, 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, or 10%) of the total membrane (e.g., plasma membrane) proteins of the producer cell (e.g., by total protein weight).

Provided herein is a method of transducing a cell comprising transducing a cell with any of the viral vectors described herein or with any of the compositions described herein. In some of any embodiments, the targeted envelope protein of the lentiviral vector or targeted lipid particle targets CD4 and the cell is a CD4+ cell. In some of any embodiments, the targeted envelope protein of the lentiviral vector targets CD8 and the cell is a CD8+ cell. In some of any embodiments, the targeted envelope protein of the lentiviral vector targets ASGR1, ASGR2 or TM4SF5 and the cell is a hepatocyte.

Provided herein is a method of delivering an exogenous agent to a subject (e.g., a human subject), the method comprising administering to the subject the targeted lipid particle of any of the embodiments provided herein or the composition of any of the embodiments provided herein, wherein the targeted lipid particle or lentiviral vector comprise the exogenous agent.

Provided herein is a method of delivering an exogenous agent to a subject (e.g., a human subject), the method comprising administering to the subject any of the compositions described herein, wherein targeted lipid particle or lentiviral vectors of the plurality comprise the exogenous agent.

Provided herein is a method of delivering a chimeric antigen receptor (CAR) to a cell, comprising contacting a cell with any of the lentiviral vectors described herein or a targeted lipid particle of any of the embodiments described herein, wherein the lentiviral vector or targeted lipid particle comprise nucleic acid encoding the CAR.

Provided herein is a method of delivering a chimeric antigen receptor (CAR) to a cell, comprising contacting a cell with any of the compositions described herein, wherein lentiviral vectors or targeted lipid particles of the plurality comprise nucleic acid encoding the CAR.

Provided herein is a method of delivering an exogenous agent to a hepatocyte, comprising contacting a cell with any of the lentiviral vectors described herein, or a targeted lipid particle or lentiviral vector of any of the embodiments described herein.

Provided herein is a method of delivering an exogenous agent to a hepatocyte, comprising contacting a cell with any of the compositions described herein, wherein lentiviral vectors or targeted lipid particles of the plurality comprise an exogenous agent for delivery to the hepatocyte. In some of any embodiments, the contacting transduces the cell with lentiviral vector or the targeted lipid particle.

Provided herein is a method of treating a disease or disorder in a subject (e.g., a human subject), the method comprising administering to the subject the targeted lipid particle of any of the embodiments provided herein or the composition of any of the embodiments provided herein.

Provided herein is a method of fusing a mammalian cell to a targeted lipid particle, the method comprising administering to the subject the targeted lipid particle of any of the embodiments provided herein or the composition of any of the embodiments provided herein. In some of any embodiments, the fusing of the mammalian cell to the targeted lipid particle delivers an exogenous agent to a subject (e.g., a human subject). In some of any embodiments, the fusing of the mammalian cell to the targeted lipid particle treats a disease or disorder in a subject (e.g., a human subject). In some of any embodiments, the targeted envelope protein of the lentiviral vector or targeted lipid particle targets CD4 and the cell is a CD4+ cell. In some of any embodiments, the targeted envelope protein of the lentiviral vector targets CD8 and the cell is a CD8+ cell. In some of any embodiments, the targeted envelope protein of the lentiviral vector targets ASGR1, ASGR2 or TM4SF5 and the cell is a hepatocyte.

In some of any embodiments, the targeted lipid particle has greater expression of the targeted envelope protein compared to a reference lipid particle that has incorporated into a similar lipid bilayer the same envelope protein but that is fused to an alternative targeting moiety. In some embodiments, the alternative targeting moiety is a single chain variable fragment (scFv). In some of any embodiments, the expression is increased by at or greater than 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 125%, 150%, 200%, 300%, 400%, 500% or more. In some of any embodiments, the expression is increased by at or greater than 1.5-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold, 15-fold, 20-fold, 30-fold or more, preferably at or about or greater than 10-fold or more.

In some of any embodiments, the titer in target cells following transduction is at or greater than 1×10⁶ transduction units (TU)/mL, at or greater than 2×10⁶ TU/mL, at or greater than 3×10⁶ TU/mL, at or greater than 4×10⁶ TU/mL, at or greater than 5×10⁶ TU/mL, at or greater than 6×10⁶ TU/mL, at or greater than 7×10⁶ TU/mL, at or greater than 8×10⁶ TU/mL, at or greater than 9×10⁶ TU/mL, or at or greater than 1×10⁷ TU/mL.

In some of any embodiments, among the population of lipid particles or lentiviral vectors in the composition, greater than at or about 50%, greater than at or about 55%, greater than at or about 60%, greater than at or about 65%, greater than at or about 70%, or greater than at or about 75% are surface positive for the targeted envelope protein. In some of any embodiments, the targeted envelope protein is present on the surface of the targeted lipid particle at a density of at least about (0.001, 0.002, 0.005, 0.01, 0.02, 0.05, 0.1, 0.2 or 0.5) targeted envelope proteins/nm².

Provided herein is a composition comprising a plurality of the targeted lipid particles of any of the embodiments described herein or a plurality of lentiviral vectors of any of the embodiments described herein, wherein the targeted envelope protein is present on the surface of the targeted lipid particles at an average density of at least about (0.001, 0.002, 0.005, 0.01, 0.02, 0.05, 0.1, 0.2 or 0.5) targeted envelope proteins/nm².

In some of any embodiments, the producer cell has greater membrane (e.g., plasma membrane) expression of the targeted envelope protein compared to a reference producer cell that has incorporated into its membrane (e.g. plasma membrane) the same envelope protein but that is fused to an alternative targeting moiety, optionally wherein the alternative targeting moiety is a single chain variable fragment (scFv). In some of any embodiments, the expression is increased by at or greater than 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 125%, 150%, 200%, 300%, 400%, 500% or more. In some of any embodiments, the expression is increased by at or greater than 1.5-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold, 15-fold, 20-fold, 30-fold or more, preferably at or about or greater than 10-fold or more. In some of any embodiments, the producer cell has the expression of the targeted envelope protein on a membrane (e.g., plasma membrane) of the producer cell is at least 20 proteins (e.g., at least 50, 100, 200, 500, 1000, 2000, 5000, or 10,000 proteins) per square micron. In some of any embodiments, the targeted envelope protein comprises at least 0.1% (e.g., at least 0.2%, 0.5%, 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, or 10%) of the total membrane (e.g., plasma membrane) proteins of the producer cell (e.g., by total protein weight).

DETAILED DESCRIPTION

Provided herein are targeted lipid particles containing a lipid bilayer enclosing a lumen or cavity and a targeted envelope protein containing (1) a henipavirus envelope attachment glycoprotein G (G protein) or biologically active portion thereof and (2) a binding domain, such as a a single domain antibody (sdAb) variable domain, in which the targeted envelope protein is embedded in the lipid bilayer of the lipid particles. In particular embodiments, the binding domain, such as a single domain antibody, is an antibody with the ability to bind, such as specifically bind, to a desired target molecule. Exemplary binding domains are described in Section II.A.2. In some embodiments, the targeted lipid particles also contains a henipavirus fusion (F) protein molecule or a biologically active portion thereof embedded in the lipid bilayer. In particular embodiments, the lipid particles can be a virus-like particle, a virus, or a viral vector, such as a lentiviral vector.

In some embodiments, one or both of the G protein and the F protein is from a Hendra (HeV) or a Nipah (NiV) virus, or is a biologically active portion thereof or is a variant or mutant thereof. In particular embodiments, both the G protein and the F protein is from a Hendra (HeV) or a Nipah (NiV) virus. In some embodiments, the fusion and attachment glycoproteins mediate cellular entry of Nipah virus.

The F protein, such as NiV-F, is a class I fusion protein that has structural and functional features in common with fusion proteins of many families (e.g., HIV-1 gp41 or influenza virus hemagglutinin [HA]), such as an ectodomain with a hydrophobic fusion peptide and two heptad repeat regions (White JM et al. 2008. Crit Rev Biochem Mol Biol 43:189-219). F proteins are synthesized as inactive precursors F₀ and are activated by proteolytic cleavage into the two disulfide-linked subunits F₁ and F₂ (Moll M. et al. 2004. J. Virol. 78(18): 9705-9712).

G proteins are attachment proteins of henipavirus (e.g. Nipah virus or Hendra virus) that are type II transmembrane glycoproteins containing an N-terminal cytoplasmic tail, a transmembrane domain, an extracellular stalk, and a globular head (Liu, Q. et al. 2015. Journal of Virology, 89(3):1838-1850). The attachment protein, NiV-G, recognizes the receptors EphrinB2 and EphrinB3. Binding of the receptor to NiV-G triggers a series of conformational changes that eventually lead to the triggering of NiV-F, which exposes the fusion peptide of NiV-F, allowing another series of conformational changes that lead to virus-cell membrane fusion (Stone J. A. et al. 2016. J Virol. 90(23): 10762-10773). EphrinB2 was previously identified as the primary NiV receptor (Negrete et al., 2005), as well as EphrinB3 as an alternate receptor (Negrete et al., 2006). In fact, NiV-G has a high affinity for EphrinB2 and B3, with affinity binding constants (Kd) in the picomolar range (Negrete et al., 2006) (Kd=0.06 nM and 0.58 nM for cell surface expressed ephrinB2 and B3, respectively).

The efficiency of transduction of targeted lipid particles can be improved by engineering hyperfusogenic mutations in one or both of NiV-F and NiV-G. Several such mutations have been previously described (see, e.g., Lee at al, 2011, Trends in Microbiology). This could be useful, for example, for maintaining the specificity and picomolar affinity of NiV-G for EphrinB2 and/or B3. Additionally, mutations in NiV-G that completely abrogate EphrinB2 and B3 binding, but that do not impact the association of this NiV-G with NiV-F, have been identified. Methods to improve targeting of lipid particles can be achieved by fusion of a binding molecule with a G protein (e.g. Niv-G, including a Niv-G with mutations to abrogate ephrin B2 and ephrin B3 binding). This could allow for altered G protein tropism allowing for targeting of other desired cell types that are not EphrinB2+ through the addition of the binding molecule molecule directed against a different cell surface molecule.

While retargeted lipid particles incorporating such binding molecules fused to a G protein have been generated, it is found herein that some some binding molecules when fused with a G protein (e.g. NiV-G) express better on the surface of lipid particles than others. For example, it is found that single domain antibodies (sdAbs), such as VHH, may express 10-fold better than a single chain variable fragment (scFv). Without wishing to be bound by theory, the increase in expression may be due to an increased stability of the retargeted G protein on the surface of the lipid particle. This greater expression can improve the ability of the lipid particle to target the target molecule (e.g. a cell surface molecule) compared to a similar lipid particle but containing an alternative binding domain, e.g. scFv, against the same target molecule.

Thus, provided herein are targeted lipid particles containing a G protein of a henipavirus (e.g. Hendra or Nipah, e.g. NiV-G) attached to a sdAb variable domain directed against or that is able to bind to a cell surface molecule on a target cell. sdAb variable domains can include those of a VL or VH only sdAb, nanobodies, camelid VHH domains, shark IgNAR or fragments thereof. In some embodiments, the sdAb is a VHH.

In aspects of the provided embodiments, a targeted lipid particle can be engineered to express a henipavirus F protein molecule or biologically active portion thereof; and a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) single domain antibody (sdAb) variable domain, wherein the F protein molecule or the biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer. In some embodiments, the sdAb variable domain is attached to the C-terminus of the G protein or the biologically active portion thereof. In some embodiments, the sdAb variable domain is attached to the G protein via a linker.

Also provided are targeted lipid particles additionally containing one or more exogenous agents, such as for delivery of a diagnostic or therapeutic agent to cells, including following in vivo administration to a subject. Also provided herein are methods and uses of the targeted lipid particles, such in diagnostic and therapeutic methods. Also provided are polynucleotides, methods for engineering, preparing, and producing the targeted lipid non-cell particles, compositions containing the particles, and kits and devices containing and for using, producing and administering the particles.

All publications, including patent documents, scientific articles and databases, referred to in this application are incorporated by reference in their entirety for all purposes to the same extent as if each individual publication were individually incorporated by reference. If a definition set forth herein is contrary to or otherwise inconsistent with a definition set forth in the patents, applications, published applications and other publications that are herein incorporated by reference, the definition set forth herein prevails over the definition that is incorporated herein by reference.

The section headings used herein are for organizational purposes only and are not to be construed as limiting the subject matter described.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1C depict characterization of cells transfected with constructs containing scFv or VHH binding modalities. FIG. 1A depicts surface expression of cells transfected with constructs containing scFV or VHH binding modalities, analyzed by flow cytometry, and depicted as median fluorescence intensity (MFI), quantified by % of His+ cells. FIG. 1B depicts binding to soluble hCD4-Fc protein of cells transfected with constructs containing scFV of VHH binding modalities analyzed by flow cytometry, and depicted as median fluorescence intensity (MFI), quantified by % Fc+ cell. FIG. 1C depicts surface expression of targeted binding sequences on 293 cells for cells transfected with constructs containing VHH binding modalities, compared to the scFv binding modalities, analyzed by flow cytometry, and depicted as median fluorescence intensity (MFI), as quantified by % of His+ cells. Empty vector and the expression vector without the binder domain were used as negative controls.

FIG. 2 depicts transduction efficacy of four exemplary constructs containing scFV or VHH binding modalities on PanT cells from peripheral blood that were negatively selected to enrich for T cells were thawed and activated with anti CD3/anti-CD28. Cells were analyzed by flow cytometry, and titer determined by % of CD4-positive cells that were GFP+.

FIGS. 3A-3B depict transduction efficiency of CD8 retargeted pseudotyped lentiviruses in an in vivo model using activated PBMCs injected intraperitonally into NOD-scid-IL2rγ^(null) mice, as analyzed by flow cytometry. Transduciton efficiency of CD8 retargeted pseudotyped lentiviruses is depicted on CD8+ (FIG. 3A) or CD8− (FIG. 3B) T cells, and titer was determined by % of CD8 positive or negative cells that were GFP+.

FIGS. 4A-4B depict the ability of CD8 retargeted pseudotyped lentiviruses containing chimeric antigen receptors (CARs) to effect killing of leukemic cells in vitro. FIG. 4A shows the ability to detect CD19+ CAR expression on CD8+ cells at 4 days post transduction. FIG. 4B shows the elimination of Nalm6 cells evaluated at 18 hours post incubation, analyzed by flow cytometry

I. DEFINITIONS

Unless defined otherwise, all terms of art, notations and other technical and scientific terms or terminology used herein are intended to have the same meaning as is commonly understood by one of ordinary skill in the art to which the claimed subject matter pertains. In some cases, terms with commonly understood meanings are defined herein for clarity and/or for ready reference, and the inclusion of such definitions herein should not necessarily be construed to represent a substantial difference over what is generally understood in the art.

Unless defined otherwise, all technical and scientific terms, acronyms, and abbreviations used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the invention pertains. Unless indicated otherwise, abbreviations and symbols for chemical and biochemical names is per IUPAC-IUB nomenclature. Unless indicated otherwise, all numerical ranges are inclusive of the values defining the range as well as all integer values in-between.

As used herein, the articles “a” and “an” refer to one or to more than one (i.e. to at least one) of the grammatical object of the article. By way of example, “an element” means one element or more than one element.

As used herein, the term “about” will be understood by persons of ordinary skill in the art and will vary to some extent on the context in which it is used. As used herein, “about” when referring to a measurable value such as an amount, a temporal duration, and the like, is meant to encompass variations of ±20% or ±10%, more preferably ±5%, even more preferably ±1%, and still more preferably ±0.1% from the specified value, as such variations are appropriate to perform the disclosed methods.

As used herein, “lipid particle” refers to any biological or synthetic particle that contains a bilayer of amphipathic lipids enclosing a lumen or cavity. Typically a lipid particle does not contain a nucleus. Examples of lipid particles include solid particles such as nanoparticles, viral-derived particles or cell-derived particles. Such lipid particles include, but are not limited to, viral particles (e.g. lentiviral particles), virus-like particles, viral vectors (e.g., lentiviral vectors) exosomes, enucleated cells, various vesicles, such as a microvesicle, a membrane vesicle, an extracellular membrane vesicle, a plasma membrane vesicle, a giant plasma membrane vesicle, an apoptotic body, a mitoparticle, a pyrenocyte, or a lysosome. In some embodiments, a lipid particle can be a fusosome. In some embodiments, the lipid particle is not a platelet.

As used herein a “biologically active portion,” such as with reference to a protein such as a G protein or an F protein, refers to a portion of the protein that exhibits or retains an activity or property of the full-length of the protein. For example, a biologically active portion of an F protein retains fusogenic activity in conjunction with the G protein when each are embedded in a lipid bilayer. A biologically active portion of the G protein retains fusogenic activity in conjunction with an F protein when each is embedded in a lipid bilayer. The retained activity and include 10%-150% or more of the activity of a full-length or wild-type F protein or G protein. Examples of biologically active portions of F and G proteins include truncations of the cytoplasmic domain, e.g. truncations of up to 1, 2, 3, 4, 5, 6, 7, 8 9, 10, 11, 12, 13, 14, 15, 20, 25, 30, 35 or more contiguous amino acids, see e.g. Khetawat and Broder 2010 Virology Journal 7:312; Witting et al. 2013 Gene Therapy 20:997-1005; published international; patent application No. WO/2013/148327.

As used herein, “fusosome” refers to a particle containing a bilayer of amphipathic lipids enclosing a lumen or cavity and a fusogen that interacts with the amphipathic lipid bilayer. In embodiments, the fusosome comprises a nucleic acid. In some embodiments, the fusosome is a membrane enclosed preparation. In some embodiments, the fusosome is derived from a source cell.

As used herein, “fusosome composition” refers to a composition comprising one or more fusosomes.

As used herein, “fusogen” refers to an agent or molecule that creates an interaction between two membrane enclosed lumens. In embodiments, the fusogen facilitates fusion of the membranes. In other embodiments, the fusogen creates a connection, e.g., a pore, between two lumens (e.g., a lumen of a retroviral vector and a cytoplasm of a target cell). In some embodiments, the fusogen comprises a complex of two or more proteins, e.g., wherein neither protein has fusogenic activity alone. In some embodiments, the fusogen comprises a targeting domain.

As used herein, a “re-targeted fusogen” refers to a fusogen that comprises a targeting moiety having a sequence that is not part of the naturally-occurring form of the fusogen. In embodiments, the fusogen comprises a different targeting moiety relative to the targeting moiety in the naturally-occurring form of the fusogen. In embodiments, the naturally-occurring form of the fusogen lacks a targeting domain, and the re-targeted fusogen comprises a targeting moiety that is absent from the naturally-occurring form of the fusogen. In embodiments, the fusogen is modified to comprise a targeting moiety. In embodiments, the fusogen comprises one or more sequence alterations outside of the targeting moiety relative to the naturally-occurring form of the fusogen, e.g., in a transmembrane domain, fusogenically active domain, or cytoplasmic domain.

As used herein, a “targeted envelope protein” refers to a polypeptide that contains a henipavirus G protein attached to a single domain antibody (sdAb) variable domain, such as a VL or VH only sdAb, nanobodies, camelid VHH domains, shark IgNAR or fragments thereof, that targets a molecule on a desired cell type. In some such embodiments, the attachment may be directly or indirectly via a linker, such as a peptide linker.

As used herein, a “targeted lipid particle” refers to a lipid particle that contains a targeted envelope protein embedded in the lipid bilayer.

As used herein, a “retroviral nucleic acid” refers to a nucleic acid containing at least the minimal sequence requirements for packaging into a retrovirus or retroviral vector, alone or in combination with a helper cell, helper virus, or helper plasmid. In some embodiments, the retroviral nucleic acid further comprises or encodes an exogenous agent, a positive target cell-specific regulatory element, a non-target cell-specific regulatory element, or a negative TCSRE. In some embodiments, the retroviral nucleic acid comprises one or more of (e.g., all of) a 5′ LTR (e.g., to promote integration), U3 (e.g., to activate viral genomic RNA transcription), R (e.g., a Tat-binding region), U5, a 3′ LTR (e.g., to promote integration), a packaging site (e.g., psi (Ψ), RRE (e.g., to bind to Rev and promote nuclear export). The retroviral nucleic acid can comprise RNA (e.g., when part of a virion) or DNA (e.g., when being introduced into a source cell or after reverse transcription in a recipient cell). In some embodiments, the retroviral nucleic acid is packaged using a helper cell, helper virus, or helper plasmid which comprises one or more of (e.g., all of) gag, pol, and env.

As used herein, a “target cell” refers to a cell of a type to which it is desired that a targeted lipid particle delivers an exogenous agent. In embodiments, a target cell is a cell of a specific tissue type or class, e.g., an immune effector cell, e.g., a T cell. In some embodiments, a target cell is a diseased cell, e.g., a cancer cell. In some embodiments, the fusogen, e.g., re-targeted fusogen leads to preferential delivery of the exogenous agent to a target cell compared to a non-target cell.

As used herein a “non-target cell” refers to a cell of a type to which it is not desired that a targeted lipid particle delivers an exogenous agent. In some embodiments, a non-target cell is a cell of a specific tissue type or class. In some embodiments, a non-target cell is a non-diseased cell, e.g., a non-cancerous cell. In some embodiments, the fusogen, e.g., re-targeted fusogen leads to lower delivery of the exogenous agent to a non-target cell compared to a target cell.

As used herein, a “single domain antibody” or “sdAb” refers to an antibody having a single monomeric domain antigen binding/recognition domain. Such antibodies include nanobodies, camelid antibodies (e.g. VHH), or shark antibodies (e.g. IgNAR). In some embodiments, a variable domain of a sdAb comprises three CDRs and four framework regions, designated FR1, CDR1, FR2, CDR2, FR3, CDR3, and FR4. In some embodiments, a sdAb variable domain may be truncated at the N-terminus or C-terminus such that it comprise only a partial FR1 and/or FR4, or lacks one or both of those framework regions, so long as the sdAb variable domain substantially maintains antigen binding and specificity.

The term “CDR” denotes a complementarity determining region as defined by at least one manner of identification to one of skill in the art. The precise amino acid sequence boundaries of a given CDR or FR can be readily determined using any of a number of well-known schemes, including those described by Kabat et al. (1991), “Sequences of Proteins of Immunological Interest,” 5th Ed. Public Health Service, National Institutes of Health, Bethesda, Md. (“Kabat” numbering scheme); Al-Lazikani et al., (1997) JMB 273, 927-948 (“Chothia” numbering scheme); MacCallum et al., J. Mol. Biol. 262:732-745 (1996), “Antibody-antigen interactions: Contact analysis and binding site topography,” J. Mol. Biol. 262, 732-745.” (“Contact” numbering scheme); Lefranc M P et al., “IMGT unique numbering for immunoglobulin and T cell receptor variable domains and Ig superfamily V-like domains,” Dev Comp Immunol, 2003 January; 27(1):55-77 (“IMGT” numbering scheme); Honegger A and Plückthun A, “Yet another numbering scheme for immunoglobulin variable domains: an automatic modeling and analysis tool,” J Mol Biol, 2001 Jun. 8; 309(3):657-70, (“Aho” numbering scheme); and Martin et al., “Modeling antibody hypervariable loops: a combined algorithm,” PNAS, 1989, 86(23):9268-9272, (“AbM” numbering scheme).

The boundaries of a given CDR or FR may vary depending on the scheme used for identification. For example, the Kabat scheme is based on structural alignments, while the Chothia scheme is based on structural information. Numbering for both the Kabat and Chothia schemes is based upon the most common antibody region sequence lengths, with insertions accommodated by insertion letters, for example, “30a,” and deletions appearing in some antibodies. The two schemes place certain insertions and deletions (“indels”) at different positions, resulting in differential numbering. The Contact scheme is based on analysis of complex crystal structures and is similar in many respects to the Chothia numbering scheme. The AbM scheme is a compromise between Kabat and Chothia definitions based on that used by Oxford Molecular's AbM antibody modeling software.

In some embodiments, CDRs can be defined in accordance with any of the Chothia numbering schemes, the Kabat numbering scheme, a combination of Kabat and Chothia, the AbM definition, and/or the contact definition. A sdAb variable domain comprises three CDRs, designated CDR1, CDR2, and CDR3. Table 1, below, lists exemplary position boundaries of CDR-H1, CDR-H2, CDR-H3 as identified by Kabat, Chothia, AbM, and Contact schemes, respectively. For CDR-H1, residue numbering is listed using both the Kabat and Chothia numbering schemes. FRs are located between CDRs, for example, with FR-H1 located before CDR-H1, FR-H2 located between CDR-H1 and CDR-H2, FR-H3 located between CDR-H2 and CDR-H3 and so forth. It is noted that because the shown Kabat numbering scheme places insertions at H35A and H35B, the end of the Chothia CDR-H1 loop when numbered using the shown Kabat numbering convention varies between H32 and H34, depending on the length of the loop.

TABLE 1 Boundaries of CDRs according to various numbering schemes. CDR Kabat Chothia AbM Contact CDR-H1 H31--H35B H26--H32 . . . 34 H26--H35B H30--H35B (Kabat Num- bering¹) CDR-H1 H31--H35 H26--H32 H26--H35 H30--H35 (Chothia Num- bering²) CDR-H2 H50--H65 H52--H56 H50--H58 H47--H58 CDR-H3 H95--H102 H95--H102 H95--H102 H93--H101 ¹Kabat et al. (1991), “Sequences of Proteins of Immunological Interest,” 5th Ed. Public Health Service, National Institutes of Health, Bethesda, MD ²Al-Lazikani et al., (1997) JMB 273, 927-948

Thus, unless otherwise specified, a “CDR” or “complementary determining region,” or individual specified CDRs (e.g., CDR-H1, CDR-H2, CDR-H3), of a given antibody or region thereof, such as a variable region thereof, should be understood to encompass a (or the specific) complementary determining region as defined by any of the aforementioned schemes. For example, where it is stated that a particular CDR (e.g., a CDR-H3) contains the amino acid sequence of a corresponding CDR in a given sdAb amino acid sequence, it is understood that such a CDR has a sequence of the corresponding CDR (e.g., CDR-H3) within the sdAb, as defined by any of the aforementioned schemes. It is understood that any antibody, such as a sdAb, includes CDRs and such can be identified according to any of the other aforementioned numbering schemes or other numbering schemes known to a skilled artisan.

As used herein, the term “specifically binds” to a target molecule, such as an antigen, means that a binding molecule, such as a single domain antibody, reacts or associates more frequently, more rapidly, with greater duration and/or with greater affinity with a particular target molecule than it does with alternative molecules. A binding molecule, such as a sdAb variable domain, “specifically binds” to a target molecule if it binds with greater affinity, avidity, more readily, and/or with greater duration than it binds to other molecules. It is understood that a binding molecule, such as a sdAb, that specifically binds to a first target may or may not specifically bind to a second target. As such, “specific binding” does not necessarily require (although it can include) exclusive binding.

As used herein, “percent (%) amino acid sequence identity” and “homology” with respect to a peptide, polypeptide or antibody sequence are defined as the percentage of amino acid residues in a candidate sequence that are identical with the amino acid residues in the specific peptide or polypeptide sequence, after aligning the sequences and introducing gaps, if necessary, to achieve the maximum percent sequence identity, and not considering any conservative substitutions as part of the sequence identity. Alignment for purposes of determining percent amino acid sequence identity can be achieved in various ways that are within the skill in the art, for instance, using publicly available computer software such as BLAST, BLAST-2, ALIGN or MEGALIGN™ (DNASTAR) software. Those skilled in the art can determine appropriate parameters for measuring alignment, including any algorithms needed to achieve maximal alignment over the full length of the sequences being compared.

An amino acid substitution may include but are not limited to the replacement of one amino acid in a polypeptide with another amino acid. Exemplary substitutions are shown in Table 2 Amino acid substitutions may be introduced into an antibody of interest and the products screened for a desired activity, for example, retained/improved binding.

TABLE 2 Original Residue Exemplary Substitutions Ala (A) Val; Leu; Ile Arg (R) Lys; Gln; Asn Asn (N) Gln; His; Asp, Lys; Arg Asp (D) Glu; Asn Cys (C) Ser; Ala Gln (Q) Asn; Glu Glu (E) Asp; Gln Gly (G) Ala His (H) Asn; Gln; Lys; Arg Ile (I) Leu; Val; Met; Ala; Phe; Norleucine Leu (L) Norleucine; Ile; Val; Met; Ala; Phe Lys (K) Arg; Gln; Asn Met (M) Leu; Phe; Ile Phe (F) Trp; Leu; Val; Ile; Ala; Tyr Pro (P) Ala Ser (S) Thr Thr (T) Val; Ser Trp (W) Tyr; Phe Tyr (Y) Trp; Phe; Thr; Ser Val (V) Ile; Leu; Met; Phe; Ala; Norleucine

Amino acids may be grouped according to common side-chain properties:

-   -   (1) hydrophobic: Norleucine, Met, Ala, Val, Leu, Ile;     -   (2) neutral hydrophilic: Cys, Ser, Thr, Asn, Gln;     -   (3) acidic: Asp, Glu;     -   (4) basic: His, Lys, Arg;     -   (5) residues that influence chain orientation: Gly, Pro;     -   (6) aromatic: Trp, Tyr, Phe.

Non-conservative substitutions will entail exchanging a member of one of these classes for another class.

The term, “corresponding to” with reference to positions of a protein, such as recitation that nucleotides or amino acid positions “correspond to” nucleotides or amino acid positions in a disclosed sequence, such as set forth in the Sequence listing, refers to nucleotides or amino acid positions identified upon alignment with the disclosed sequence based on structural sequence alignment or using a standard alignment algorithm, such as the GAP algorithm. For example, corresponding residues of a similar sequence (e.g. fragment or species variant) can be determined by alignment to a reference sequence by structural alignment methods. By aligning the sequences, one skilled in the art can identify corresponding residues, for example, using conserved and identical amino acid residues as guides.

The term “isolated” as used herein refers to a molecule that has been separated from at least some of the components with which it is typically found in nature or produced. For example, a polypeptide is referred to as “isolated” when it is separated from at least some of the components of the cell in which it was produced. Where a polypeptide is secreted by a cell after expression, physically separating the supernatant containing the polypeptide from the cell that produced it is considered to be “isolating” the polypeptide. Similarly, a polynucleotide is referred to as “isolated” when it is not part of the larger polynucleotide (such as, for example, genomic DNA or mitochondrial DNA, in the case of a DNA polynucleotide) in which it is typically found in nature, or is separated from at least some of the components of the cell in which it was produced, for example, in the case of an RNA polynucleotide. Thus, a DNA polynucleotide that is contained in a vector inside a host cell may be referred to as “isolated”.

The term “effective amount” as used herein means an amount of a pharmaceutical composition which is sufficient enough to significantly and positively modify the symptoms and/or conditions to be treated (e.g., provide a positive clinical response). The effective amount of an active ingredient for use in a pharmaceutical composition will vary with the particular condition being treated, the severity of the condition, the duration of treatment, the nature of concurrent therapy, the particular active ingredient(s) being employed, the particular pharmaceutically-acceptable excipient(s) and/or carrier(s) utilized, and like factors with the knowledge and expertise of the attending physician.

An “exogenous agent” as used herein with reference to a targeted lipid particle, refers to an agent that is neither comprised by nor encoded in the corresponding wild-type virus or fusogen made from a corresponding wild-type source cell. In some embodiments, the exogenous agent does not naturally exist, such as a protein or nucleic acid that has a sequence that is altered (e.g., by insertion, deletion, or substitution) relative to a naturally occurring protein. In some embodiments, the exogenous agent does not naturally exist in the source cell. In some embodiments, the exogenous agent exists naturally in the source cell but is exogenous to the virus. In some embodiments, the exogenous agent does not naturally exist in the recipient cell. In some embodiments, the exogenous agent exists naturally in the recipient cell, but is not present at a desired level or at a desired time. In some embodiments, the exogenous agent comprises RNA or protein.

As used herein, a “promoter” refers to a cis-regulatory DNA sequence that, when operably linked to a gene coding sequence, drives transcription of the gene. The promoter may comprise a transcription factor binding sites. In some embodiments, a promoter works in concert with one or more enhancers which are distal to the gene.

As used herein, a composition refers to any mixture of two or more products, substances, or compounds, including cells. It may be a solution, a suspension, liquid, powder, a paste, aqueous, non-aqueous or any combination thereof.

As used herein, the term “pharmaceutically acceptable” refers to a material, such as carrier or diluent, which does not abrogate the biological activity or properties of the compound, and is relatively nontoxic, i.e., the material may be administered to an individual without causing undesirable biological effects or interacting in a deleterious manner with any of the components of the composition in which it is contained.

As used herein, the term “pharmaceutical. composition” refers to a mixture of at least one compound of the invention with other chemical components, such as carriers, stabilizers, diluents, dispersing agents, suspending agents, thickening agents, and/or excipients. The pharmaceutical composition facilitates administration of the compound to an organism. Multiple techniques of administering a compound exist in the art including, but not limited to, intravenous, oral, aerosol, parenteral, ophthalmic, pulmonary and topical administration.

A “disease” or “disorder” as used herein refers to a condition where treatment is needed and/or desired.

As used herein, the terms “treat,” “treating,” or “treatment” refer to ameliorating a disease or disorder, e.g., slowing or arresting or reducing the development of the disease or disorder or reducing at least one of the clinical symptoms thereof. For purposes of this disclosure, ameliorating a disease or disorder can include obtaining a beneficial or desired clinical result that includes, but is not limited to, any one or more of: alleviation of one or more symptoms, diminishment of extent of disease, preventing or delaying spread (for example, metastasis, for example metastasis to the lung or to the lymph node) of disease, preventing or delaying recurrence of disease, delay or slowing of disease progression, amelioration of the disease state, inhibiting the disease or progression of the disease, inhibiting or slowing the disease or its progression, arresting its development, and remission (whether partial or total).

The terms “individual” and “subject” are used interchangeably herein to refer to an animal; for example a mammal. The term patient includes human and veterinary subjects. In some embodiments, methods of treating mammals, including, but not limited to, humans, rodents, simians, felines, canines, equines, bovines, porcines, ovines, caprines, mammalian laboratory animals, mammalian farm animals, mammalian sport animals, and mammalian pets, are provided. The subject can be male or female and can be any suitable age, including infant, juvenile, adolescent, adult, and geriatric subjects. In some examples, an “individual” or “subject” refers to an individual or subject in need of treatment for a disease or disorder. In some embodiments, the subject to receive the treatment can be a patient, designating the fact that the subject has been identified as having a disorder of relevance to the treatment, or being at adequate risk of contracting the disorder. In particular embodiments, the subject is a human, such as a human patient.

II. TARGETED LIPID PARTICLES (E.G. LENTIVIRAL VECTORS)

Provided herein are targeted lipid particles that comprise a henipavirus F protein molecule or biologically active portion thereof, and a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion, wherein each of (i) and (ii) is exposed on the outer surface of the targeted lipid particle. In some embodiments, the binding domain is a single domain antibody. In some embodiments, the binding domain is a single chain variable fragment. In particular embodiments, the provided lipid particles exhibit fusogenic activity, which is mediated by the targeted envelope protein that facilitates binding to a target cell and contains the G protein or biologically active portion thereof, and the F glycoprotein that is involved in facilitating the merger or fusion of the two lumens of the lipid particle and the target cell membranes.

Provided herein are targeted lipid particles that comprise a henipavirus F protein molecule or biologically active portion thereof, and a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a single domain antibody (sdAb) variable domain, wherein the single domain antibody is attached to the C-terminus of the G protein or the biologically active portion, wherein each of (i) and (ii) is exposed on the outer surface of the targeted lipid particle. In particular embodiments, the provided lipid particles exhibit fusogenic activity, which is mediated by the targeted envelope protein that facilitates binding to a target cell and contains the G protein or biologically active portion thereof, and the F glycoprotein that is involved in facilitating the merger or fusion of the two lumens of the lipid particle and the target cell membranes.

In some of any embodiment, the targeted lipid particles are viral particles or viral-like particles. In some aspects, such targeted lipid particles contain viral nucleic acid, such as retroviral nucleic acid, for example lentiviral nucleic acid. In particular embodiments, any provided targeted lipid particles, such as a viral particle or viral-like particle, is replication defective. In some embodiments, the targeted lipid particle is a lentiviral vector, in which the lentiviral vector is pseudotyped with the henipavirus F protein and the targeted envelope protein.

For instance, provided herein is a pseudotyped lentiviral vector that comprises a henipavirus F protein molecule or biologically active portion thereof, and a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion, wherein each of (i) and (ii) is exposed on the outer surface of the targeted lipid particle. In some embodiments, the binding domain is a single domain antibody. In some embodiments, the binding domain is a single chain variable fragment.

In some embodiments, the targeted lipid particle provided herein (e.g. targeted lentiviral vector) has increased or greater expression of the targeted envelope protein compared to a reference lipid particle (e.g. reference lentiviral vector) that incorporates a similar envelope protein but that is fused to an alternative targeting moiety other than a sdAb variable domain, such as a single chain variable fragment (scFv). In some embodiments, such targeted lipid particles are produced by pseudotyping of lipid particles (e.g lentiviral particles) following co-transfection of the packaging cells with the transfer, envelope, and gag-pol plasmids.

In some embodiments, the expression is increased by at or greater than 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 125%, 150%, 200%, 300%, 400%, 500% or more, compared to a reference lipid particle (e.g. reference lentiviral vector), e.g. a reference lipid particle containing a similar envelope protein but that is fused to an scFv. In some examples, the expression is increased by at or greater than 1.5-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold, 15-fold, 20-fold, 30-fold or more, compared to a reference lipid particle (e.g. reference lentiviral vector), e.g. a reference lipid particle containing a similar envelope protein but that is fused to an scFv. In some embodiments, expression can be assayed in vitro using flow cytometry, e.g. FACs. In some embodiments, expression can be depicted as the number or density of targeted envelope protein on the surface of a targeted lipid particle (e.g. targeted lentiviral vector). In some embodiments, expression can be depicted as the mean fluorescent intensity (MFI) of surface expression of the targeted envelope protein on the surface of a targeted lipid particle (e.g. targeted lentiviral vector). In some embodiments, expression can be depicted as the percent of lipid particle (e.g. lentiviral vectors) in a population that are surface positive for the targeted envelope protein.

In some embodiments, in a population of targeted lipid particles (e.g. targeted lentiviral vectors) greater than at or about 50% of the lipid particles are surface positive for the targeted envelope protein. For example, in a population of provided targeted lipid particles (e.g. targeted lentiviral vectors) greater than at or about 55%, greater than at or about 60%, greater than at or about 65%, greater than at or about 70%, greater than at or about 75% of the cells in the population are surface positive for the targeted envelope protein.

In some embodiments, titer of the targeted lipid particles following introduction into target cells, such as by transduction (e.g. transduced cells), is increased compared to titer into the same target cells of reference lipid particles (e.g. reference lentiviral vector) that incorporate a similar envelope protein but fused to an alternative targeting moiety other than a sdAb variable domain, such as a single chain variable fragment (scFv). Typically, the alternative targeting moiety recognizes or binds the same target molecule as the sdAb variable domain of the targeted envelope protein of the targeted lipid particles. In some embodiments, the titer is increased by at or greater than 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 125%, 150%, 200%, 300%, 400%, 500% or more, compared to titer of a reference lipid particle (e.g. reference lentiviral vector), e.g. a reference lipid particle containing a similar envelope protein but that is fused to an scFv. In some examples, the titer is increased by at or greater than 1.5-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold, 15-fold, 20-fold, 30-fold or more, compared to the titer of a reference lipid particle (e.g. reference lentiviral vector), e.g. a reference lipid particle containing a similar envelope protein but that is fused to an scFv. In some embodiments, the titer of the targeted lipid particles in target cells (e.g. transduced cells) is greater than at or about 1×10⁶ transduction units (TU)/mL. For example, the titer of the targeted lipid particles in target cells (e.g. transduced cells) is greater than at or about 2×10⁶ TU/mL, greater than at or about 3×10⁶ TU/mL, greater than at or about 4×10⁶ TU/mL, greater than at or about 5×10⁶ TU/mL, greater than at or about 6×10⁶ TU/mL, greater than at or about 7×10⁶ TU/mL, greater than at or about 8×10⁶ TU/mL, greater than at or about 9×10⁶ TU/mL, or greater than at or about 1×10⁷ TU/mL.

A. Targeted Envelope Protein (e.g. Henipavirus Plus Binding Domain)

In some embodiments, the targeted lipid particle (e.g. lentiviral vector) includes a targeted envelope protein exposed on the surface of the targeted lipid particle (e.g. lentiviral vector).

In some embodiments, the targeted envelope protein contains a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a binding domain that binds to a cell surface molecule on a target cell. In some embodiments, the binding domain is a single domain antibody (sdAb). In some embodiments, the binding domain is a single chain variable fragment (scFv). The binding domain can be linked directly or indirectly to the G protein. In particular embodiments, the binding domain is linked to the C-terminus (C-terminal amino acid) of the G protein or the biologically active portion thereof. The linkage can be via a peptide linker, such as a flexible peptide linker.

I. Protein

In some embodiments, the targeted envelope protein contains a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain or biologically active portion thereof. In some embodiments, the sdAb binds to a cell surface molecule on a target cell. The sdAb variable domain can be linked directly or indirectly to the G protein. In particular embodiments, the sdAb variable domain is linked to the C-terminus (C-terminal amino acid) of the G protein or the biologically active portion thereof. The linkage can be via a peptide linker, such as a flexible peptide linker.

In some embodiments, an binding domain (e.g. sdAb) binds to a cell surface antigen of a cell. In some embodiments, a cell surface antigen is characteristic of one type of cell. In some embodiments, a cell surface antigen is characteristic of more than one type of cell.

In some embodiments, the binding domain (e.g. sdAb) variable domain binds a cell surface molecule or antigen. In some embodiments, the cell surface molecule is ASGR1, ASGR2, TM4SF5, CD8, CD4, or low density lipoprotein receptor (LDL-R). In some embodiments, the cell surface molecule is ASGR1. In some embodiments, the cell surface molecule is ASGR2. In some embodiments, the cell surface molecule is TM4SF5. In some embodiments, the cell surface molecule is CD8. In some embodiments, the cell surface molecule is CD4. In some embodiments, the cell surface molecule is LDL-R.

In some embodiments the G protein is a Henipavirus G protein or a biologically active portion thereof. In some embodiments, the Henipavirus G protein is a Hendra (HeV) virus G protein, a Nipah (NiV) virus G-protein (NiV-G), a Cedar (CedPV) virus G-protein, a Mojiang virus G-protein, a bat Paramyxovirus G-protein or a biologically active portion thereof. Table 3 provides non-limiting examples of G proteins.

The attachment G proteins are type II transmembrane glycoproteins containing an N-terminal cytoplasmic tail (e.g. corresponding to amino acids 1-49 of SEQ ID NO:9), a transmembrane domain (e.g. corresponding to amino acids 50-70 of SEQ ID NO:9), and an extracellular domain containing an extracellular stalk (e.g. corresponding to amino acids 71-187 of SEQ ID NO:9), and a globular head (corresponding to amino acids 188-602 of SEQ ID NO:9). The N-terminal cytoplasmic domain is within the inner lumen of the lipid bilayer and the C-terminal portion is the extracellular domain that is exposed on the outside of the lipid bilayer. Regions of the stalk in the C-terminal region (e.g. corresponding to amino acids 159-167 of NiV-G) have been shown to be involved in interactions with F protein and triggering of F protein fusion (Liu et al. 2015 J of Virology 89:1838). In wild-type G protein, the globular head mediates receptor binding to henipavirus entry receptors eprhin B2 and ephrin B3, but is dispensable for membrane fusion (Brandel-Tretheway et al. Journal of Virology. 2019. 93(13)e00577-19). In particular embodiments herein, tropism of the G protein is altered by linkage of the G protein or biologically active fragment thereof (e.g. cytoplasmic truncation) to a sdAb variable domain. Binding of the G protein to a binding partner can trigger fusion mediated by a compatible F protein or biologically active portion thereof. G protein sequences disclosed herein are predominantly disclosed as expressed sequences including an N-terminal methionine required for start of translation. As such N-terminal methionines are commonly cleaved co- or post-translationally, the mature protein sequences for all G protein sequences disclosed herein are also contemplated as lacking the N-terminal methionine.

G glycoproteins are highly conserved between henipavirus species. For example, the G protein of NiV and HeV viruses share 79% amino acids identity. Studies have shown a high degree of compatibility among G proteins with F proteins of different species as demonstrated by heterotypic fusion activation (Brandel-Tretheway et al. Journal of Virology. 2019). As described further below, a re-targeted lipid particle can contain heterologous G and F proteins from different species.

TABLE 3 Henipavirus protein G sequence clusters. Column 1, Genbank ID includes the Genbank ID of the whole genome sequence of the virus that is the centroid sequence of the cluster. Column 2, nucleotides of CDS provides the nucleotides corresponding to the CDS of the gene in the whole genome. Column 3, Full Gene Name, provides the full name of the gene including Genbank ID, virus species, strain, and protein name. Column 4, Sequence, provides the amino acid sequence of the gene. Column 5, #Sequences/Cluster, provides the number of sequences that cluster with this centroid sequence. Column 6 provides the SEQ ID numbers for the described sequences. SEQ ID NO (without Nucleotides SEQ N- Genbank of Full sequence #Sequences/ ID terminal ID CDS ID Sequence Cluster NO methionine) AF017  8913- gb: AF017149| MMADSKLVSLNNNLSGKIKDQGKVIKN 14 18 52 149 10727 Organism: Hen YYGTMDIKKINDGLLDSKILGAFNTVIA dra LLGSIIIIVMNIMIIQNYTRTTDNQALIKES virus|Strain LQSVQQQIKALTDKIGFEIGPKVSLIDTSS Name: UNKN TITIPANIGLLGSKISQSTSSINENVNDKC OWN- KFTLPPLKIHECNISCPNPLPFREYRPISQ AF017149|Pro GVSDLVGLPNQICLQKTTSTILKPRLISY tein TLPINTREGVCITDPLLAVDNGFFAYSHL Name: glycopr EKIGSCTRGIAKQRIIGVGEVLDRGDKVP otein|Gene SMFMTNVWTPPNPSTIHHCSSTYHEDFY Symbol: G YTLCAVSHVGDPILNSTSWTESLSLIRLA VRPKSDSGDYNQKYIAITKVERGKYDK VMPYGPSGIKQGDTLYFPAVGFLPRTEF QYNDSNCPIIHCKYSKAENCRLSMGVNS KSHYILRSGLLKYNLSLGGDIILQFIEIAD NRLTIGSPSKIYNSLGQPVFYQASYSWD TMIKLGDVDTVDPLRVQWRNNSVISRP GQSQCPRFNVCPEVCWEGTYNDAFLIDR LNWVSAGVYLNSNQTAENPVFAVFKDN EILYQVPLAEDDTNAQKTITDCFLLENVI WCISLVEIYDTGDSVIRPKLFAVKIPAQC SES AF212  8943- gb: AF2123021 MPAENKKVRFENTTSDKGKIPSKVIKSY 14 28 44 302 10751 Organism: Nip YGTMDIKKINEGLLDSKILSAFNTVIALL ah virus|Strain GSIVIIVMNIMIIQNYTRSTDNQAVIKDA Name: UNKN LQGIQQQIKGLADKIGTEIGPKVSLIDTSS OWN- TITIPANIGLLGSKISQSTASINENVNEKC AF212302|Pro KFTLPPLKIHECNISCPNPLPFREYRPQTE tein GVSNLVGLPNNICLQKTSNQILKPKLISY Name: attachm TLPVVGQSGTCITDPLLAMDEGYFAYSH ent LERIGSCSRGVSKQRIIGVGEVLDRGDEV glycoprotein|G PSLFMTNVWTPPNPNTVYHCSAVYNNE ene Symbol: G FYYVLCAVSTVGDPILNSTYWSGSLMM TRLAVKPKSNGGGYNQHQLALRSIEKG RYDKVMPYGPSGIKQGDTLYFPAVGFL VRTEFKYNDSNCPITKCQYSKPENCRLS MGIRPNSHYILRSGLLKYNLSDGENPKV VFIEISDQRLSIGSPSKIYDSLGQPVFYQA SFSWDTMIKFGDVLTVNPLVVNWRNNT VISRPGQSQCPRFNTCPEICWEGVYNDA FLIDRINWISAGVFLDSNQTAENPVFTVF KDNEILYRAQLASEDTNAQKTITNCFLL KNKIWCISLVEIYDTGDNVIRPKLFAVKI PEQCT JQ001  8170- gb: JQ001776:  MLSQLQKNYLDNSNQQGDKMNNPDKK 3 29 54 776 10275 8170- LSVNFNPLELDKGQKDLNKSYYVKNKN 10275|Organis YNVSNLLNESLHDIKFCIYCIFSLLIIITIIN m: Cedar IITISIVITRLKVHEENNGMESPNLQSIQD virus|S train SLSSLTNMINTEITPRIGILVTATSVTLSSS Name: CG1a|Pr INYVGTKTNQLVNELKDYITKSCGFKVP otein ELKLHECNISCADPKISKSAMYSTNAYA Name: attachm ELAGPPKIFCKSVSKDPDFRLKQIDYVIP ent VQQDRSICMNNPLLDISDGFFTYIHYEGI glycoprotein|G NSCKKSDSFKVLLSHGEIVDRGDYRPSL ene Symbol: G YLLSSHYHPYSMQVINCVPVTCNQSSFV FCHISNNTKTLDNSDYSSDEYYITYFNGI DRPKTKKIPINNMTADNRYIHFTFSGGG GVCLGEEFIIPVTTVINTDVFTHDYCESF NCSVQTGKSLKEICSESLRSPTNSSRYNL NGIMIISQNNMTDFKIQLNGITYNKLSFG SPGRLSKTLGQVLYYQSSMSWDTYLKA GFVEKWKPFTPNWMNNTVISRPNQGNC PRYHKCPEICYGGTYNDIAPLDLGKDMY VSVILDSDQLAENPEITVFNSTTILYKER VSKDELNTRSTTTSCFLFLDEPWCISVLE TNRFNGKSIRPEIYSYKIPKYC NC_02  9117- gb: NC_02525 MPQKTVEFINMNSPLERGVSTLSDKKTL 2 30 55 5256 11015 6: 9117- NQSKITKQGYFGLGSHSERNWKKQKNQ 11015|Organis NDHYMTVSTMILEILVVLGIMFNLIVLT m: Bat MVYYQNDNINQRMAELTSNITVLNLNL Paramyxovirus NQLTNKIQREIIPRITLIDTATTITIPSAITY Eid_he1/GH- ILATLTTRISELLPSINQKCEFKTPTLVLN M74a/GHA/20 DCRINCTPPLNPSDGVKMSSLATNLVAH 09|Strain GPSPCRNFSSVPTIYYYRIPGLYNRTALD Name: BatPV/ ERCILNPRLTISSTKFAYVHSEYDKNCTR Eid_he1/GH- GFKYYELMTFGEILEGPEKEPRMFSRSF M74a/GHA/20 YSPTNAVNYHSCTPIVTVNEGYFLCLEC 09|Protein TSSDPLYKANLSNSTFHLVILRHNKDEKI Name: glycopr VSMPSFNLSTDQEYVQIIPAEGGGTAESG otein|Gene NLYFPCIGRLLHKRVTHPLCKKSNCSRT Symbol: G DDESCLKSYYNQGSPQHQVVNCLIRIRN AQRDNPTWDVITVDLTNTYPGSRSRIFG SFSKPMLYQSSVSWHTLLQVAEITDLDK YQLDWLDTPYISRPGGSECPFGNYCPTV CWEGTYNDVYSLTPNNDLFVTVYLKSE QVAENPYFAIFSRDQILKEFPLDAWISSA RTTTISCFMFNNEIWCIAALEITRLNDDII RPIYYSFWLPTDCRTPYPHTGKMTRVPL RSTYNY NC_02  8716- gb: NC_02535 MATNRDNTITSAEVSQEDKVKKYYGVE 2 31 56 5352 11257 2: 8716- TAEKVADSISGNKVFILMNTLLILTGAIIT 11257|Organis ITLNITNLTAAKSQQNMLKIIQDDVNAK m: Mojiang LEMFVNLDQLVKGEIKPKVSLINTAVSV virus|Strain SIPGQISNLQTKFLQKYVYLEESITKQCT Name: Tonggu CNPLSGIFPTSGPTYPPTDKPDDDTTDDD an1|Protein KVDTTIKPIEYPKPDGCNRTGDHFTMEP Name: attachm GANFYTVPNLGPASSNSDECYTNPSFSIG ent SSIYMFSQEIRKTDCTAGEILSIQIVLGRI glycoprotein|G VDKGQQGPQASPLLVWAVPNPKIINSCA ene Symbol: G VAAGDEMGWVLCSVTLTAASGEPIPHM FDGFWLYKLEPDTEVVSYRITGYAYLLD KQYDSVFIGKGGGIQKGNDLYFQMYGL SRNRQSFKALCEHGSCLGTGGGGYQVL CDRAVMSFGSEESLITNAYLKVNDLASG KPVIIGQTFPPSDSYKGSNGRMYTIGDKY GLYLAPSSWNRYLRFGITPDISVRSTTWL KSQDPIMKILSTCTNTDRDMCPEICNTRG YQDIFPLSEDSEYYTYIGITPNNGGTKNF VAVRDSDGHIASIDILQNYYSITSATISCF MYKDEIWCIAITEGKKQKDNPQRIYAHS YKIRQMCYNMKSATVTVGNAKNITIRR Y

In some embodiments, the G protein has a sequence set forth in any of SEQ ID NOS: 9, 18, 28, 29, 30, 31, 44, 52, or 54-56 or is a functionally active variant or biologically active portion thereof that has a sequence that is at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% identical to any one of SEQ ID NOS: 9, 18, 28, 29, 30, 31, 44, 52, or 54-56. In particular embodiments, the G protein or functionally active variant or biologically active portion is a protein that retains fusogenic activity in conjunction with a Henipavirus F protein, such as an F protein set forth in Section I.B (e.g. NiV-F or HeV-F). Fusogenic activity includes the activity of the G protein in conjunction with a Henipavirus F protein to promote or facilitate fusion of two membrane lumens, such as the lumen of the targeted lipid particle having embedded in its lipid bilayer a henipavirus F and G protein, and a cytoplasm of a target cell, e.g. a cell that contains a surface receptor or molecule that is recognized or bound by the targeted envelope protein. In some embodiments, the F protein and G protein are from the same Henipavirus species (e.g. NiV-G and NiV-F). In some embodiments, the F protein and G protein are from different Henipavirus species (e.g. NiV-G and HeV-F).

In particular embodiments, the G protein has the sequence of amino acids set forth in SEQ ID NO: 9, SEQ ID NO: 28, SEQ ID NO: 18, SEQ ID NO: 30, SEQ ID NO: 31, SEQ ID NO: 44, SEQ ID NO: 52 or SEQ ID NO: 54-56 or is a functionally active variant thereof or a biologically active portion thereof that retains fusogenic activity. In some embodiments, the functionally active variant comprises an amino acid sequence having at least at or about 80%, at least at or about 85%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:28, SEQ ID NO: 18, SEQ ID NO:30, SEQ ID NO: 31, SEQ ID NO: 44, SEQ ID NO: 52 or SEQ ID NO: 54-56 and retains fusogenic activity in conjunction with a Henipavirus F protein (e.g., NiV-F or HeV-F). In some embodiments, the biologically active portion has an amino acid sequence having at least at or about 80%, at least at or about 85%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:28, SEQ ID NO: 18, SEQ ID NO:30 SEQ ID NO: 31, SEQ ID NO: 44, SEQ ID NO: 52 or SEQ ID NO: 54-56 and retains fusogenic activity in conjunction with a Henipavirus F protein (e.g., NiV-F or HeV-F).

Reference to retaining fusogenic activity includes activity (in conjunction with a Henipavirus F protein) that is between at or about 10% and at or about 150% or more of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:28, SEQ ID NO: 18, SEQ ID NO:30, SEQ ID NO: 31, SEQ ID NO: 44, SEQ ID NO: 52 or SEQ ID NO: 54-56 such as at least or at least about 10% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 15% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 20% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 25% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 30% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 35% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 40% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 45% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 50% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 55% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 60% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 65% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 70% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 75% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 80% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 85% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 90% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 95% of the level or degree of fusogenic activity of the corresponding wild-type G protein, such as at least or at least about 100% of the level or degree of fusogenic activity of the corresponding wild-type G protein, or such as at least or at least about 120% of the level or degree of fusogenic activity of the corresponding wild-type G protein.

In some embodiments the G protein is a mutant G protein that is a functionally active variant or biologically active portion containing one or more amino acid mutations, such as one or more amino acid insertions, deletions, substitutions or truncations. In some embodiments, the mutations described herein relate to amino acid insertions, deletions, substitutions or truncations of amino acids compared to a reference G protein sequence. In some embodiments, the reference G protein sequence is the wild-type sequence of a G protein or a biologically active portion thereof. In some embodiments, the functionally active variant or the biologically active portion thereof is a mutant of a wild-type Hendra (HeV) virus G protein, a wild-type Nipah (NiV) virus G-protein (NiV-G), a wild-type Cedar (CedPV) virus G-protein, a wild-type Mojiang virus G-protein, a wild-type bat Paramyxovirus G-protein or biologically active portion thereof. In some embodiments, the wild-type G protein has the sequence set forth in any one of SEQ ID NOS: 9, 18, 28, 29, 30, 31 SEQ ID NO: 44, SEQ ID NO: 52 or SEQ ID NO: 54-56.

In some embodiments, the G protein is a mutant G protein that is a biologically active portion that is an N-terminally and/or C-terminally truncated fragment of a wild-type Hendra (HeV) virus G protein, a wild-type Nipah (NiV) virus G-protein (NiV-G), a wild-type Cedar (CedPV) virus G-protein, a wild-type Mojiang virus G-protein, a wild-type bat Paramyxovirus G-protein. In particular embodiments, the truncation is an N-terminal truncation of all or a portion of the cytoplasmic domain. In some embodiments, the mutant G protein is a biologically active portion that is truncated and lacks up to 49 contiguous amino acid residues at or near the N-terminus of the wild-type G protein, such as a wild-type G protein set forth in any one of SEQ ID NOS: 9, 18, 28, 29, 30, 31, SEQ ID NO: 44, SEQ ID NO: 52 or SEQ ID NO: 54-56. In some embodiments, the mutant F protein is truncated and lacks up to 49 contiguous amino acids, such as up to 49, 48, 47, 46, 45, 44, 43, 42, 41, 40, 30, 38, 37, 36, 35, 34, 33, 32, 31, 30, 29, 28, 27, 26, 25, 24, 23, 22, 21, 20, 19, 18, 17, 16, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1 contiguous amino acids at the N-terminus of the wild-type G protein.

In some embodiments, the G protein is a wild-type Nipah virus G (NiV-G) protein or a Hendra virus G protein, or is a functionally active variant or biologically active portion thereof. In some embodiments, the G protein is a NiV-G protein that has the sequence set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, or is a functional variant or a biologically active portion thereof that has an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44.

In some embodiments, the G protein is a mutant NiV-G protein that is a biologically active portion of a wild-type NiV-G. In some embodiments, the biologically active portion is an N-terminally truncated fragment. In some embodiments, the mutant NiV-G protein is truncated and lacks up to 5 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 6 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 7 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 8 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 9 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 10 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 11 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 12 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 13 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 14 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 15 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 16 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 17 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 18 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 19 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 20 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 21 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 22 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 23 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 24 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 25 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 26 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 27 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 28 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 29 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 30 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 31 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 32 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 33 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 34 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 35 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 36 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 37 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 38 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 39 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 40 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 41 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 42 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 43 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), up to 44 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), or up to 45 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

In some embodiments, the NiV-G protein is a biologically active portion that does not contain a cytoplasmic domain. In some embodiments, the NiV-G protein without the cytoplasmic domain is encoded by SEQ ID NO: 32.

In some embodiments, the mutant NiV-G protein comprises a sequence set forth in any of SEQ ID NOS: 10-15, 35-40, 45-50, 22, 53 or SEQ ID NO: 32, or is a functional variant thereof that has an amino acid sequence having at least at or 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NOs: 10-15, 35-40, 45-50, 22, 53 or SEQ ID NO:32.

In some embodiments, the mutant NiV-G protein has a 5 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), such as set forth in SEQ ID NO: 10 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:10 or such as set forth in SEQ ID NO: 35 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:35 or such as set forth in SEQ ID NO: 45 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:45. In some embodiments, the mutant NiV-G protein has a 10 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), such as set forth in SEQ ID NO: 11 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:11, or such as set forth in SEQ ID NO: 36 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:36 or such as set forth in SEQ ID NO: 46 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:46.

In some embodiments, the mutant NiV-G protein has a 15 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), such as set forth in SEQ ID NO: 12 or a functional variant thereof that has an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:12 or such as set forth in SEQ ID NO: 37 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:37 or such as set forth in SEQ ID NO: 47 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:47. In some embodiments, the mutant NiV-G protein has a 20 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44) such as set forth in SEQ ID NO: 13, or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:13 or such as set forth in SEQ ID NO: 38 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:38 or such as set forth in SEQ ID NO: 48 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:48. In some embodiments, the mutant NiV-G protein has a 25 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), such as set forth in SEQ ID NO: 14 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:14 or such as set forth in SEQ ID NO: 39 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:39 or such as set forth in SEQ ID NO: 49 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:49. In some embodiments, the mutant NiV-G protein has a 30 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), such as set forth in SEQ ID NO: 15 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:15 or such as set forth in SEQ ID NO: 40 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:40, or such as set forth in SEQ ID NO: 50 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:50. In some embodiments, the mutant NiV-G protein has a 34 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), such as set forth in SEQ ID NO: 22 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:22 or such as set forth in SEQ ID NO: 53 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:53. In some embodiments, the mutant NiV-G protein lacks the N-terminal cytoplasmic domain of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44), such as set forth in SEQ ID NO:32 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:32.

In some embodiments, the mutant G protein is a mutant HeV-G protein that has the sequence set forth in SEQ ID NO:18 or 52, or is a functional variant or biologically active portion thereof that has an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at or about 85%, at least at or about 86%, at least at or about 87%, at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:18 or 52.

In some embodiments, the G protein is a mutant HeV-G protein that is a biologically active portion of a wild-type HeV-G. In some embodiments, the biologically active portion is an N-terminally truncated fragment. In some embodiments, the mutant HeV-G protein is truncated and lacks up to 5 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 6 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 7 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 8 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 9 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 10 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 11 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 12 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 13 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 14 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 15 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 16 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 17 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 18 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 19 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 20 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 21 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 22 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 23 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 24 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 25 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 26 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 27 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 28 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 29 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 30 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 31 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 32 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 33 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 34 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 35 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 36 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 37 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 38 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 39 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 40 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 41 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 42 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 43 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), up to 44 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52), or up to 45 contiguous amino acid residues at or near the N-terminus of the wild-type HeV-G protein (SEQ ID NO:18 or 52). In some embodiments, the HeV-G protein is a biologically active portion that does not contain a cytoplasmic domain. In some embodiments, the mutant HeV-G protein lacks the N-terminal cytoplasmic domain of the wild-type HeV-G protein (SEQ ID NO:18 or 52), such as set forth in SEQ ID NO:33 or a functional variant thereof having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:33.

In some embodiments, the G protein or the functionally active variant or biologically active portion thereof binds to Ephrin B2 or Ephrin B3. In some aspects, the G protein has the sequence of amino acids set forth in any one of SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or is a functionally active variant thereof or a biologically active portion thereof that is able to bind to Ephrin B2 or Ephrin B3. In some embodiments, the functionally active variant or biologically active portion has an amino acid sequence having at least about 80%, at least about 85%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, and retains binding to Ephrhin B2 or B3. Reference to retaining binding to Ephrin B2 or B3 includes binding that is at least or at least about 5% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 10% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 15% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 20% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 25% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion, 30% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 35% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 40% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 45% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 50% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 55% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 60% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 65% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, 70% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, such as at least or at least about 75% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, such as at least or at least about 80% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, such as at least or at least about 85% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, such as at least or at least about 90% of the level or degree of binding of the corresponding wild-type G protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof, or such as at least or at least about 95% of the level or degree of binding of the corresponding wild-type protein, such as set forth in SEQ ID NO:9, SEQ ID NO:18 or SEQ ID NO:28, SEQ ID NO:29, SEQ ID NO: 44, SEQ ID NO:30 or SEQ ID NO:31, or a functionally active variant or biologically active portion thereof. In some embodiments, the G protein is NiV-G or a functionally active variant or biologically active portion thereof and binds to Ephrin B2 or Ephrin B3. In some aspects, the NiV-G has the sequence of amino acids set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, or is a functionally active variant thereof or a biologically active portion thereof that is able to bind to Ephrin B2 or Ephrin B3. In some embodiments, the functionally active variant or biologically active portion has an amino acid sequence having at least about 80%, at least about 85%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44 and retains binding to Eprhin B2 or B3. Exemplary biologically active portions include N-terminally truncated variants lacking all or a portion of the cytoplasmic domain, e.g. 1 or more, such as 1 to 49 contiguous N-terminal amino acid residues, e.g. set forth in any one of SEQ ID NOS: 10-15, 35-40, 45-50 and 32. Reference to retaining binding to Ephrin B2 or B3 includes binding that is at least or at least about 5% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 10% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 15% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 20% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 25% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 30% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 35% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 40% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 45% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 50% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 55% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 60% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 65% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, 70% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, such as at least or at least about 75% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, such as at least or at least about 80% of the level or degree of binding of the corresponding wild-type NIV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, such as at least or at least about 85% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, such as at least or at least about 90% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44, or such as at least or at least about 95% of the level or degree of binding of the corresponding wild-type NiV-G, such as set forth in SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44.

In some embodiments, the G protein is HeV-G or a functionally active variant or biologically active portion thereof and binds to Ephrin B2 or Ephrin B3. In some aspects, the HeV-G has the sequence of amino acids set forth in SEQ ID NO:18 or 52, or is a functionally active variant thereof or a biologically active portion thereof that is able to bind to Ephrin B2 or Ephrin B3. In some embodiments, the functionally active variant or biologically active portion has an amino acid sequence having at least about 80%, at least about 85%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:18 or 52 and retains binding to Eprhin B2 or B3. Exemplary biologically active portions include N-terminally truncated variants lacking all or a portion of the cytoplasmic domain, e.g. 1 or more, such as 1 to 49 contiguous N-terminal amino acid residues, e.g. set forth in any one of SEQ ID NO:33. Reference to retaining binding to Ephrin B2 or B3 includes binding that is at least or at least about 5% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 10% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 15% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 20% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 25% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 30% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 35% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 40% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 45% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 50% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 55% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 60% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 65% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, 70% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, such as at least or at least about 75% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, such as at least or at least about 80% of the level or degree of binding of the corresponding wild-type NIV-G, such as set forth in SEQ ID NO:18 or 52, such as at least or at least about 85% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, such as at least or at least about 90% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52, or such as at least or at least about 95% of the level or degree of binding of the corresponding wild-type HeV-G, such as set forth in SEQ ID NO:18 or 52.

In some embodiments, the G protein or the biologically thereof is a mutant G protein that exhibits reduced binding for the native binding partner of a wild-type G protein. In some embodiments, the mutant G protein or the biologically active portion thereof is a mutant of wild-type Niv-G and exhibits reduced binding to one or both of the native binding partners Ephrin B2 or Ephrin B3. In some embodiments, the mutant G-protein or the biologically active portion, such as a mutant NiV-G protein, exhibits reduced binding to the native binding partner. In some embodiments, the reduced binding to Ephrin B2 or Ephrin B3 is reduced by greater than at or about 5%, at or about 10%, at or about 15%, at or about 20%, at or about 25%, at or about 30%, at or about 40%, at or about 50%, at or about 60%, at or about 70%, at or about 80%, at or about 90%, or at or about 100%.

In some embodiments, the mutations described herein can improve transduction efficiency. In some embodiments, the mutations described herein allow for specific targeting of other desired cell types that are not Ephrin B2 or Ephrin B3. In some embodiments, the mutations described herein result in at least the partial inability to bind at least one natural receptor, such has reduce the binding to at least one of Ephrin B2 or Ephrin B3. In some embodiments, the mutations described herein interfere with natural receptor recognition.

In some embodiments, the G protein contains one or more amino acid substitutions in a residue that is involved in the interaction with one or both of Ephrin B2 and Ephrin B3. In some embodiments, the amino acid substitutions correspond to mutations E501A, W504A, Q530A and E533A with reference to numbering set forth in SEQ ID NO:28.

In some embodiments, the G protein is a mutant G protein containing one or more amino acid substitutions selected from the group consisting of E501A, W504A, Q530A and E533A with reference to numbering set forth in SEQ ID NO:28. In some embodiments, the G protein is a mutant G protein that contains one or more amino acid substitutions elected from the group consisting of E501A, W504A, Q530A and E533A with reference to SEQ ID NO:28 and is a biologically active portion thereof containing an N-terminal truncation. In some embodiments, the mutant NiV-G protein or the biologically active portion thereof is truncated and lacks up to 5 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 6 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 7 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 8 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 9 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), up to 10 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 11 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 12 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 13 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 14 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), up to 15 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 16 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 17 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 18 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 19 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), up to 20 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 21 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 22 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 23 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 24 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), up to 25 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 26 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 27 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 28 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 29 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), up to 30 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (EQ ID NO:28), up to 31 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 32 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 33 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 34 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), 35 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:28), up to 36 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (EQ ID NO:28), up to 37 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (EQ ID NO:28), up to 38 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (EQ ID NO:28), up to 39 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (EQ ID NO:28), or up to 40 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (EQ ID NO:28).

In some embodiments, the mutant NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 16 or 51 or an amino acid sequence having at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:16 or 51. In particular embodiments, the G protein has the sequence of amino acids set forth in SEQ ID NO: 16 or 51.

In some embodiments, the targeted envelope protein contains a G protein or a functionally active variant or biologically active portion and an sdAb variable domain, in which the targeted envelope protein exhibits increased binding for another molecule that is different from the native binding partner of a wild-type G protein. In some embodiments, the molecule can be a protein expressed on the surface of desired target cell. In some embodiments, the increased binding to the other molecule is increased by greater than at or about 25%, at or about 30%, at or about 40%, at or about 50%, at or about 60%, at or about 70%, at or about 80%, at or about 90%, or at or about 100%. In particular embodiments, the binding confers re-targeted binding compared to the binding of a wild-type G protein in which a new or different binding activity is conferred.

2. Binding Domain

In some embodiments, the binding domain can be any agent that binds to a cell surface molecule on a target cells. In some embodiments, the binding domain can be an antibody or an antibody portion or fragment.

The binding domain may be modulated to have different binding strengths. For example, scFvs and antibodies with various binding strengths may be used to alter the fusion activity of the chimeric attachment proteins towards cells that display high or low amounts of the target antigen. For example DARPins with different affinities may be used to alter the fusion activity towards cells that display high or low amounts of the target antigen. Binding domains may also be modulated to target different regions on the target ligand, which will affect the fusion rate with cells displaying the target.

The binding domain may comprise a humanized antibody molecule, intact IgA, IgG, IgE or IgM antibody; bi- or multi-specific antibody (e.g., Zybodies®, etc); antibody fragments such as Fab fragments, Fab′ fragments, F(ab′)2 fragments, Fd′ fragments, Fd fragments, and isolated CDRs or sets thereof; single chain Fvs; polypeptide-Fc fusions; single domain antibodies (e.g., shark single domain antibodies such as IgNAR or fragments thereof); cameloid antibodies; masked antibodies (e.g., Probodies®); Small Modular ImmunoPharmaceuticals (“SMIPsTM”); single chain or Tandem diabodies (TandAb®); VHHs; Anticalins®; Nanobodies®; minibodies; BiTE®s; ankyrin repeat proteins or DARPINs®; Avimers®; DARTs; TCR-like antibodies; Adnectins®; Affilins®; Trans-bodies®; Affibodies®; TrimerX®; MicroProteins; Fynomers®, Centyrins®; and KALBITOR®s. A targeting moiety can also include an antibody or an antigen-binding fragment thereof (e.g., Fab, Fab′, F(ab′)2, Fv fragments, scFv antibody fragments, disulfide-linked Fvs (sdFv), a Fd fragment consisting of the VH and CH1 domains, linear antibodies, single domain antibodies such as sdAb (either VL or VH), nanobodies, or camelid VHH domains), an antigen-binding fibronectin type III (Fn3) scaffold such as a fibronectin polypeptide minibody, a ligand, a cytokine, a chemokine, or a T cell receptor (TCRs).

In some embodiments, the binding domain is a single chain molecule. In some embodiments, the binding domain is a single domain antibody. In some embodiments, the binding domain is a single chain variable fragment. In particular embodiments, the binding domain contains an antibody variable sequence (s) that is human or humanized.

In some embodiments, the binding domain is a single domain antibody. In some embodiments, the single domain antibody can be human or humanized In some embodiments, the single domain antibody or portion thereof is naturally occurring. In some embodiments, the single domain antibody or portion thereof is synthetic.

In some embodiments, the single domain antibodies are antibodies whose complementary determining regions are part of a single domain polypeptide. In some embodiments, the single domain antibody is a heavy chain only antibody variable domain. In some embodiments, the single domain antibody does not include light chains.

In some embodiments, the heavy chain antibody devoid of light chains is referred to as VHH. In some embodiments, the single domain antibody antibodies have a molecular weight of 12-15 kDa. In some embodiments, the single domain antibody antibodies include camelid antibodies or shark antibodies. In some embodiments, the single domain antibody molecule is derived from antibodies raised in Camelidae species, for example in camel, llama, dromedary, alpaca, vicuna and guanaco. In some embodiments, the single domain antibody is referred to as immunoglobulin new antigen receptors (IgNARs) and is derived from cartilaginous fishes. In some embodiments, the single domain antibody is generated by splitting dimeric variable domains of human or mouse IgG into monomers and camelizing critical residues.

In some embodiments, the single domain antibody can be generated from phage display libraries. In some embodiments, the phage display libraries are generated from a VHH repertoire of camelids immunized with various antigens, as described in Arbabi et al., FEBS Letters, 414, 521-526 (1997); Lauwereys et al., EMBO J., 17, 3512-3520 (1998); Decanniere et al., Structure, 7, 361-370 (1999). In some embodiments, the phage display library is generated comprising antibody fragments of a non-immunized camelid. In some embodiments, single domain antibodies a library of human single domain antibodies is synthetically generated by introducing diversity into one or more scaffolds.

In some embodiments, the C-terminus of the single domain antibody is attached to the C-terminus of the G protein or biologically active portion thereof. In some embodiments, the N-terminus of the single domain antibody is exposed on the exterior surface of the lipid bilayer. In some embodiments, the N-terminus of the single domain antibody binds to a cell surface molecule of a target cell. In some embodiments, the single domain antibody specifically binds to a cell surface molecule present on a target cell. In some embodiments, the cell surface molecule is a protein, glycan, lipid or low molecular weight molecule.

In some embodiments, the cell surface molecule of a target cell is an antigen or portion thereof. In some embodiments, the single domain antibody or portion thereof is an antibody having a single monomeric domain antigen binding/recognition domain that is able to bind selectively to a specific antigen. In some embodiments, the single domain antibody binds an antigen present on a target cell.

Exemplary cells include polymorphonuclear cells (also known as PMN, PML, PMNL, or granulocytes), stem cells, embryonic stem cells, neural stem cells, mesenchymal stem cells (MSCs), hematopoietic stem cells (HSCs), human myogenic stem cells, muscle-derived stem cells (MuStem), embryonic stem cells (ES or ESCs), limbal epithelial stem cells, cardio-myogenic stem cells, cardiomyocytes, progenitor cells, immune effector cells, lymphocytes, macrophages, dendritic cells, natural killer cells, T cells, cytotoxic T lymphocytes, allogenic cells, resident cardiac cells, induced pluripotent stem cells (iPS), adipose-derived or phenotypic modified stem or progenitor cells, CD133+ cells, aldehyde dehydrogenase-positive cells (ALDH+), umbilical cord blood (UCB) cells, peripheral blood stem cells (PBSCs), neurons, neural progenitor cells, pancreatic beta cells, glial cells, or hepatocytes,

In some embodiments, the target cell is a cell of a target tissue. The target tissue can include liver, lungs, heart, spleen, pancreas, gastrointestinal tract, kidney, testes, ovaries, brain, reproductive organs, central nervous system, peripheral nervous system, skeletal muscle, endothelium, inner ear, or eye.

In some embodiments, the target cell is a muscle cell (e.g., skeletal muscle cell), kidney cell, liver cell (e.g. hepatocyte), or a cadiac cell (e.g. cardiomyocyte). In some embodiments, the target cell is a cardiac cell, e.g., a cardiomyocyte (e.g., a quiescent cardiomyocyte), a hepatoblast (e.g., a bile duct hepatoblast), an epithelial cell, a T cell (e.g. a naive T cell), a macrophage (e.g., a tumor infiltrating macrophage), or a fibroblast (e.g., a cardiac fibroblast).

In some embodiments, the target cell is a tumor-infiltrating lymphocyte, a T cell, a neoplastic or tumor cell, a virus-infected cell, a stem cell, a central nervous system (CNS) cell, a hematopoeietic stem cell (HSC), a liver cell or a fully differentiated cell. In some embodiments, the target cell is a CD3+ T cell, a CD4+ Tcell, a CD8+ T cell, a hepatocyte, a haematepoietic stem cell, a CD34+ haematepoietic stem cell, a CD105+ haematepoietic stem cell, a CD117+ haematepoietic stem cell, a CD105+ endothelial cell, a B cell, a CD20+ B cell, a CD19+ B cell, a cancer cell, a CD133+ cancer cell, an EpCAM+ cancer cell, a CD19+ cancer cell, a Her2/Neu+ cancer cell, a GluA2+ neuron, a GluA4+ neuron, a NKG2D+ natural killer cell, a SLC1A3+ astrocyte, a SLC7A10+ adipocyte, or a CD30+ lung epithelial cell.

In some embodiments, the target cell is an antigen presenting cell, an MHC class II+ cell, a professional antigen presenting cell, an atypical antigen presenting cell, a macrophage, a dendritic cell, a myeloid dendritic cell, a plasmacyteoid dendritic cell, a CD11c+ cell, a CD11b+ cell, a splenocyte, a B cell, a hepatocyte, a endothelial cell, or a non-cancerous cell).

In some embodiments, the cell surface molecule is any one of CD8, CD4, asialoglycoprotein receptor 2 (ASGR2), transmembrane 4 L6 family member 5 (TM4SF5), low density lipoprotein receptor (LDLR) or asialoglycoprotein 1 (ASGR1).

In some embodiments, the G protein or functionally active variant or biologically active portion thereof is linked directly to the sdAb variable domain. In some embodiments, the targeted envelope protein is a fusion protein that has the following structure: (N′-single domain antibody-C′)-(C′-G protein-N′).

In some embodiments, the G protein or functionally active variant or biologically active portion thereof is linked indirectly via a linker to the the sdAb variable domain. In some embodiments, the linker is a peptide linker. In some embodiments, the linker is a chemical linker.

In some embodiments, the linker is a peptide linker and the targeted envelope protein is a fusion protein containing the G protein or functionally active variant or biologically active portion thereof linked via a peptide linker to the sdAb variable domain. In some embodiments, the targeted envelope protein is a fusion protein that has the following structure: (N′-single domain antibody-C′)-Linker-(C′-G protein-N′).

In some embodiments, the peptide linker is up to 65 amino acids in length. In some embodiments, the peptide linker comprises from or from about 2 to 65 amino acids, 2 to 60 amino acids, 2 to 56 amino acids, 2 to 52 amino acids, 2 to 48 amino acids, 2 to 44 amino acids, 2 to 40 amino acids, 2 to 36 amino acids, 2 to 32 amino acids, 2 to 28 amino acids, 2 to 24 amino acids, 2 to 20 amino acids, 2 to 18 amino acids, 2 to 14 amino acids, 2 to 12 amino acids, 2 to 10 amino acids, 2 to 8 amino acids, 2 to 6 amino acids, 6 to 65 amino acids, 6 to 60 amino acids, 6 to 56 amino acids, 6 to 52 amino acids, 6 to 48 amino acids, 6 to 44 amino acids, 6 to 40 amino acids, 6 to 36 amino acids, 6 to 32 amino acids, 6 to 28 amino acids, 6 to 24 amino acids, 6 to 20 amino acids, 6 to 18 amino acids, 6 to 14 amino acids, 6 to 12 amino acids, 6 to 10 amino acids, 6 to 8 amino acids, 8 to 65 amino acids, 8 to 60 amino acids, 8 to 56 amino acids, 8 to 52 amino acids, 8 to 48 amino acids, 8 to 44 amino acids, 8 to 40 amino acids, 8 to 36 amino acids, 8 to 32 amino acids, 8 to 28 amino acids, 8 to 24 amino acids, 8 to 20 amino acids, 8 to 18 amino acids, 8 to 14 amino acids, 8 to 12 amino acids, 8 to 10 amino acids, 10 to 65 amino acids, 10 to 60 amino acids, 10 to 56 amino acids, 10 to 52 amino acids, 10 to 48 amino acids, 10 to 44 amino acids, 10 to 40 amino acids, 10 to 36 amino acids, 10 to 32 amino acids, 10 to 28 amino acids, 10 to 24 amino acids, 10 to 20 amino acids, 10 to 18 amino acids, 10 to 14 amino acids, 10 to 12 amino acids, 12 to 65 amino acids, 12 to 60 amino acids, 12 to 56 amino acids, 12 to 52 amino acids, 12 to 48 amino acids, 12 to 44 amino acids, 12 to 40 amino acids, 12 to 36 amino acids, 12 to 32 amino acids, 12 to 28 amino acids, 12 to 24 amino acids, 12 to 20 amino acids, 12 to 18 amino acids, 12 to 14 amino acids, 14 to 65 amino acids, 14 to 60 amino acids, 14 to 56 amino acids, 14 to 52 amino acids, 14 to 48 amino acids, 14 to 44 amino acids, 14 to 40 amino acids, 14 to 36 amino acids, 14 to 32 amino acids, 14 to 28 amino acids, 14 to 24 amino acids, 14 to 20 amino acids, 14 to 18 amino acids, 18 to 65 amino acids, 18 to 60 amino acids, 18 to 56 amino acids, 18 to 52 amino acids, 18 to 48 amino acids, 18 to 44 amino acids, 18 to 40 amino acids, 18 to 36 amino acids, 18 to 32 amino acids, 18 to 28 amino acids, 18 to 24 amino acids, 18 to 20 amino acids, 20 to 65 amino acids, 20 to 60 amino acids, 20 to 56 amino acids, 20 to 52 amino acids, 20 to 48 amino acids, 20 to 44 amino acids, 20 to 40 amino acids, 20 to 36 amino acids, 20 to 32 amino acids, 20 to 28 amino acids, 20 to 26 amino acids, 20 to 24 amino acids, 24 to 65 amino acids, 24 to 60 amino acids, 24 to 56 amino acids, 24 to 52 amino acids, 24 to 48 amino acids, 24 to 44 amino acids, 24 to 40 amino acids, 24 to 36 amino acids, 24 to 32 amino acids, 24 to 30 amino acids, 24 to 28 amino acids, 28 to 65 amino acids, 28 to 60 amino acids, 28 to 56 amino acids, 28 to 52 amino acids, 28 to 48 amino acids, 28 to 44 amino acids, 28 to 40 amino acids, 28 to 36 amino acids, 28 to 34 amino acids, 28 to 32 amino acids, 32 to 65 amino acids, 32 to 60 amino acids, 32 to 56 amino acids, 32 to 52 amino acids, 32 to 48 amino acids, 32 to 44 amino acids, 32 to 40 amino acids, 32 to 38 amino acids, 32 to 36 amino acids, 36 to 65 amino acids, 36 to 60 amino acids, 36 to 56 amino acids, 36 to 52 amino acids, 36 to 48 amino acids, 36 to 44 amino acids, 36 to 40 amino acids, 40 to 65 amino acids, 40 to 60 amino acids, 40 to 56 amino acids, 40 to 52 amino acids, 40 to 48 amino acids, 40 to 44 amino acids, 44 to 65 amino acids, 44 to 60 amino acids, 44 to 56 amino acids, 44 to 52 amino acids, 44 to 48 amino acids, 48 to 65 amino acids, 48 to 60 amino acids, 48 to 56 amino acids, 48 to 52 amino acids, 50 to 65 amino acids, 50 to 60 amino acids, 50 to 56 amino acids, 50 to 52 amino acids, 54 to 65 amino acids, 54 to 60 amino acids, 54 to 56 amino acids, 58 to 65 amino acids, 58 to 60 amino acids, or 60 to 65 amino acids. In some embodiments, the peptide linker is a polypeptide that is 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, or 65 amino acids in length.

In particular embodiments, the linker is a flexible peptide linker. In some such embodiments, the linker is 1-20 amino acids, such as 1-20 amino acids predominantly composed of glycine. In some embodiments, the linker is 1-20 amino acids, such as 1-20 amino acids predominantly composed of glycine and serine. In some embodiments, the linker is a flexible peptide linker containing amino acids Glycine and Serine, referred to as GS-linkers. In some embodiments, the peptide linker includes the sequences GS, GGS, GGGGS (SEQ ID NO:43), GGGGGS (SEQ ID NO:41) or combinations thereof. In some embodiments, the polypeptide linker has the sequence (GGS)n, wherein n is 1 to 10. In some embodiments, the polypeptide linker has the sequence (GGGGS)n, (SEQ ID NO:42) wherein n is 1 to 10. In some embodiments, the polypeptide linker has the sequence (GGGGGS)n (SEQ ID NO:27), wherein n is 1 to 6.

3. Polynucleotides

Provided herein are polynucleotides comprising a nucleic acid sequence encoding a targeted envelope protein. In some embodiments, the polynucleotides comprise a nucleic acid sequence encoding a G protein or biologically active portion thereof. In some embodiments, the polynucleotides further comprise a nucleic acid sequence encoding a single domain antibody (sdAb) variable domain or biologically active portion thereof. The polynucleotides may include a sequence of nucleotides encoding any of the targeted envelope proteins described above. The polynucleotide can be a synthetic nucleic acid. Also provided are expression vector containing any of the provided polynucleotides.

In some of any embodiments, expression of natural or synthetic nucleic acids is typically achieved by operably linking a nucleic acid encoding the gene of interest to a promoter and incorporating the construct into an expression vector. In some embodiments, vectors can be suitable for replication and integration in eukaryotes. In some embodiments, cloning vectors contain transcription and translation terminators, initiation sequences, and promoters useful for expression of the desired nucleic acid sequence. In some of any embodiments, a plasmid comprises a promoter suitable for expression in a cell.

In some embodiments, the polynucleotides contain at least one promoter that is operatively linked to control expression of the targeted envelope protein containing the G protein and the single domain antibody (sdAb) variable domain. For expression of the targeted envelope protein, at least one module in each promoter functions to position the start site for RNA synthesis. The best known example of this is the TATA box, but in some promoters lacking a TATA box, such as the promoter for the mammalian terminal deoxynucleotidyl transferase gene and the promoter for the SV40 genes, a discrete element overlying the start site itself helps to fix the place of initiation.

In some embodiments, additional promoter elements, e.g., enhancers, regulate the frequency of transcriptional initiation. In some embodiments, additional promoter elements are located in the region 30-110 bp upstream of the start site, although a number of promoters have recently been shown to contain functional elements downstream of the start site as well. In some embodiments, spacing between promoter elements frequently is flexible, so that promoter function is preserved when elements are inverted or moved relative to one another. In some embodiments, the thymidine kinase (tk) promoter, the spacing between promoter elements can be increased to 50 bp apart before activity begins to decline. In some embodiments, depending on the promoter, individual elements can function either cooperatively or independently to activate transcription.

A promoter may be one naturally associated with a gene or polynucleotide sequence, as may be obtained by isolating the 5′ non-coding sequences located upstream of the coding segment and/or exon. Such a promoter can be referred to as “endogenous.” Similarly, an enhancer may be one naturally associated with a polynucleotide sequence, located either downstream or upstream of that sequence. Alternatively, certain advantages will be gained by positioning the coding polynucleotide segment under the control of a recombinant or heterologous promoter, which refers to a promoter that is not normally associated with a polynucleotide sequence in its natural environment. A recombinant or heterologous enhancer refers also to an enhancer not normally associated with a polynucleotide sequence in its natural environment. Such promoters or enhancers may include promoters or enhancers of other genes, and promoters or enhancers isolated from any other prokaryotic, viral, or eukaryotic cell, and promoters or enhancers not “naturally occurring,” i.e., containing different elements of different transcriptional regulatory regions, and/or mutations that alter expression. In addition to producing nucleic acid sequences of promoters and enhancers synthetically, sequences may be produced using recombinant cloning and/or nucleic acid amplification technology, including PCR, in connection with the compositions disclosed herein (U.S. Pat. Nos. 4,683,202 and 5,928,906).

In some embodiments, a suitable promoter is the immediate early cytomegalovirus (CMV) promoter sequence. In some embodiments, the promoter sequence is a strong constitutive promoter sequence capable of driving high levels of expression of any polynucleotide sequence operatively linked thereto. In some embodiments, a suitable promoter is Elongation Growth Factor-la (EF-1 a). In some embodiments, other constitutive promoter sequences may also be used, including, but not limited to the simian virus 40 (SV40) early promoter, mouse mammary tumor virus (MMTV), human immunodeficiency virus (HIV) long terminal repeat (LTR) promoter, MoMuLV promoter, an avian leukemia virus promoter, an Epstein-Barr virus immediate early promoter, a Rous sarcoma virus promoter, as well as human gene promoters such as, but not limited to, the actin promoter, the myosin promoter, the hemoglobin promoter, and the creatine kinase promoter.

In some embodiments, the promoter is an inducible promoter. In some embodiments, the inducible promoter provides a molecular switch capable of turning on expression of the polynucleotide sequence which it is operatively linked when such expression is desired, or turning off the expression when expression is not desired. In some embodiments, inducible promoters comprise metallothionine promoter, a glucocorticoid promoter, a progesterone promoter, and a tetracycline promoter.

In some embodiments, exogenously controlled inducible promoters can be used to regulate expression of the G protein and single domain antibody (sdAb) variable domain. For example, radiation-inducible promoters, heat-inducible promoters, and/or drug-inducible promoters can be used to selectively drive transgene expression in, for example, targeted regions. In such embodiments, the location, duration, and level of transgene expression can be regulated by the administration of the exogenous source of induction.

In some embodiments, expression of the targeted envelope protein containing a G protein and single domain antibody (sdAb) variable domain is regulated using a drug-inducible promoter. For example, in some cases, the promoter, enhancer, or transactivator comprises a Lac operator sequence, a tetracycline operator sequence, a galactose operator sequence, a doxycycline operator sequence, a rapamycin operator sequence, a tamoxifen operator sequence, or a hormone-responsive operator sequence, or an analog thereof. In some instances, the inducible promoter comprises a tetracycline response element (TRE). In some embodiments, the inducible promoter comprises an estrogen response element (ERE), which can activate gene expression in the presence of tamoxifen. In some instances, a drug-inducible element, such as a TRE, can be combined with a selected promoter to enhance transcription in the presence of drug, such as doxycycline. In some embodiments, the drug-inducible promoter is a small molecule-inducible promoter.

Any of the provided polynucleotides can be modified to remove CpG motifs and/or to optimize codons for translation in a particular species, such as human, canine, feline, equine, ovine, bovine, etc. species. In some embodiments, the polynucleotides are optimized for human codon usage (i.e., human codon-optimized). In some embodiments, the polynucleotides are modified to remove CpG motifs. In other embodiments, the provided polynucleotides are modified to remove CpG motifs and are codon-optimized, such as human codon-optimized. Methods of codon optimization and CpG motif detection and modification are well-known. Typically, polynucleotide optimization enhances transgene expression, increases transgene stability and preserves the amino acid sequence of the encoded polypeptide.

In order to assess the expression of the targeted envelope protein, the expression vector to be introduced into a cell can also contain either a selectable marker gene or a reporter gene or both to facilitate identification and selection of expressing particles, e.g. viral particles. In other embodiments, the selectable marker may be carried on a separate piece of DNA and used in a co-transfection procedure. Both selectable markers and reporter genes may be flanked with appropriate regulatory sequences to enable expression in the host cells. Useful selectable markers are known in the art and include, for example, antibiotic-resistance genes, such as neo and the like.

Reporter genes are used for identifying potentially transfected cells and for evaluating the functionality of regulatory sequences. Reporter genes that encode for easily assayable proteins are well known in the art. In general, a reporter gene is a gene that is not present in or expressed by the recipient organism or tissue and that encodes a protein whose expression is manifested by some easily detectable property, e.g., enzymatic activity. Expression of the reporter gene is assayed at a suitable time after the DNA has been introduced into the recipient cells.

Suitable reporter genes may include genes encoding luciferase, beta-galactosidase, chloramphenicol acetyl transferase, secreted alkaline phosphatase, or the green fluorescent protein gene (see, e.g., Ui-Tei et al., 2000, FEBS Lett. 479:79-82). Suitable expression systems are well known and may be prepared using well known techniques or obtained commercially. Internal deletion constructs may be generated using unique internal restriction sites or by partial digestion of non-unique restriction sites. Constructs may then be transfected into cells that display high levels of the desired polynucleotide and/or polypeptide expression. In general, the construct with the minimal 5′ flanking region showing the highest level of expression of reporter gene is identified as the promoter. Such promoter regions may be linked to a reporter gene and used to evaluate agents for the ability to modulate promoter-driven transcription.

B. Fusogen (e.g. Henipavirus F Protein)

In some embodiments, the targeted lipid particle comprises one or more fusogens. In some embodiments, the targeted lipid particle contains an exogenous or overexpressed fusogen. In some embodiments, the fusogen is disposed in the lipid bilayer. In some embodiments, the fusogen facilitates the fusion of the targeted lipid particle to a membrane. In some embodiments, the membrane is a plasma cell membrane.

In some embodiments, fusogens comprise protein based, lipid based, and chemical based fusogens. In some embodiments, the targeted lipid particle comprises a first fusogen comprising a protein fusogen and a second fusogen comprising a lipid fusogen or chemical fusogen. In some embodiments, the fusogen binds fusogen binding partner on a target cell surface.

In some embodiments, the fusogen comprises a protein with a hydrophobic fusion peptide domain. In some embodiments, the fusogen comprises a henipavirus F protein molecule or biologically active portion thereof. In some embodiments, the Henipavirus F protein is a Hendra (Hey) virus F protein, a Nipah (NiV) virus F-protein, a Cedar (CedPV) virus F protein, a Mojiang virus F protein or a bat Paramyxovirus F protein or a biologically active portion thereof.

Table 4 provides non-limiting examples of F proteins. In some embodiments, the N-terminal hydrophobic fusion peptide domain of the F protein molecule or biologically active portion thereof is exposed on the outside of lipid bilayer.

F proteins of henipaviruses are encoded as F₀ precursors containing a signal peptide (e.g. corresponding to amino acid residues 1-26 of SEQ ID NO:1). Following cleavage of the signal peptide, the mature F₀ (e.g. SEQ ID NO:2) is transported to the cell surface, then endocytosed and cleaved by cathepsin L (e.g. between amino acids 109-110 of SEQ ID NO:1) into the mature fusogenic subunits F1 (e.g. corresponding to amino acids 110-546 of SEQ ID NO:1; set forth in SEQ ID NO:4) and F2 (e.g. corresponding to amino acid residues 27-109 of SEQ ID NO:1; set forth in SEQ ID NO:3). The F1 and F2 subunits are associated by a disulfide bond and recycled back to the cell surface. The F1 subunit contains the fusion peptide domain located at the N terminus of the F1 subunit (e.g. .g. corresponding to amino acids 110-129 of SEQ ID NO:1) where it is able to insert into a cell membrane to drive fusion. In particular cases, fusion activity is blocked by association of the F protein with G protein, until G engages with a target molecule resulting in its disassociation from F and exposure of the fusion peptide to mediate membrane fusion.

Among different henipavirus species, the sequence and activity of the F protein is highly conserved. For examples, the F protein of NiV and HeV viruses share 89% amino acid sequence identity. Further, in some cases, the henipavirus F proteins exhibit compatibility with G proteins from other species to trigger fusion (Brandel-Tretheway et al. Journal of Virology. 2019. 93(13):e00577-19). In some aspects or the provided re-targeted lipid particles, the F protein is heterologous to the G protein, i.e. the F and G protein or biologically active portions are from different henipavirus species. For example, the F protein is from Hendra virus and the G protein is from Nipah virus. In other aspects, the F protein can be a chimeric F protein containing regions of F proteins from different species of Henipavirus. In some embodiments, switching a region of amino acid residues of the F protein from one species of Henipavirus to another can result in fusion to the G protein of the species comprising the amino acid insertion. (Brandel-Tretheway et al. 2019). In some cases, the chimeric F protein contains an extracellular domain from one henipavirus species and a transmembrane and/or cytoplasmic domain from a different henipavirus species. For example, the F protein contains an extracellular domain of Hendra virus and a transmembrane/cytoplasmic domain of Nipah virus. F protein sequences disclosed herein are predominantly disclosed as expressed sequences including an N-terminal signal sequence. As such N-terminal signal sequences are commonly cleaved co- or post-translationally, the mature protein sequences for all F protein sequences disclosed herein are also contemplated as lacking the N-terminal signal sequence.

TABLE 4 Henipavirus F sequence clusters. Column 1, Genbank ID includes the Genbank ID of the whole genome sequence of the virus that is the centroid sequence of the cluster. Column 2, Nucleotides of CDS provides the nucleotides corresponding to the CDS of the gene in the whole genome. Column 3, Full Gene Name, provides the full name of the gene including Genbank ID, virus species, strain, and protein name. Nipah virus F protein is >80% identical to that of Hendra virus and is found within the same sequence cluster. Column 4, Sequence, provides the amino acid sequence of the gene. Column 5, #Sequences/Cluster, provides the number of sequences that cluster with this centroid sequence. Column 6 provides the SEQ ID numbers for the described sequences. SEQ ID Gen- Nucleotides SEQ (without bank of Full Gene #Sequences/ ID signal ID CDS Name Sequence Cluster NO sequence) AF 6618 gb: AF017149| MATQEVRLKCLLCGIIVLVLSLEGLGILHYEK 29 17 59 017 - Organism: Hen LSKIGLVKGITRKYKIKSNPLTKDIVIKMIPNVS 149 8258 dra virus|Strain NVSKCTGTVMENYKSRLTGILSPIKGAIELYN Name: UNKN NNTHDLVGDVKLAGVVMAGIAIGIATAAQIT OWN- AGVALYEAMKNADNINKLKSSIESTNEAVVK AF017149|Prot LQETAEKTVYVLTALQDYINTNLVPTIDQISC ein KQTELALDLALSKYLSDLLFVFGPNLQDPVSN Name: fusion|G SMTIQAISQAFGGNYETLLRTLGYATEDFDDL ene Symbol: F LESDSIAGQIVYVDLSSYYIIVRVYFPILTEIQQ AYVQELLPVSENNDNSEWISIVPNEVLIRNTLI SNIEVKYCLITKKSVICNQDYATPMTASVREC LTGSTDKCPRELVVSSHVPRFALSGGVLFANC ISVTCQCQTTGRAISQSGEQTLLMIDNTTCTTV VLGNIIISLGKYLGSINYNSESIAVGPPVYTDK VDISSQISSMNQSLQQSKDYIKEAQKILDTVNP SLISMLSMIILYVLSIAALCIGLITFISFVIVEKK RGNYSRLDDRQVRPVSNGDLYYIGT Q9I Additional in MVVILDKRCYCNLLILILMISECSVGILHYEKL 1 2 H6 cluster: SKIGLVKGVTRKYKIKSNPLTKDIVIKMIPNVS 3 sp|Q9IH63|FU NMSQCTGSVMENYKTRLNGILTPIKGALEIYK S_NIPAV NNTHDLVGDVRLAGVIMAGVAIGIATAAQIT Fusion AGVALYEAMKNADNINKLKSSIESTNEAVVK glycoprotein LQETAEKTVYVLTALQDYINTNLVPTIDKISC F0 OS = Nipah KQTELSLDLALSKYLSDLLFVFGPNLQDPVSN virus SMTIQAISQAFGGNYETLLRTLGYATEDFDDL LESDSITGQIIYVDLSSYYIIVRVYFPILTEIQQA YIQELLPVSFNNDNSEWISIVPNFILVRNTLISN IEIGFCLITKRSVICNQDYATPMTNNMRECLTG STEKCPRELVVSSHVPRFALSNGVLFANCISVT CQCQTTGRAISQSGEQTLLMIDNTTCPTAVLG NVIISLGKYLGSVNYNSEGIAIGPPVFTDKVDI SSQISSMNQSLQQSKDYIKEAQRLLDTVNPSLI SMLSMIILYVLSIASLCIGLITFISFIIVEKKRNT YSRLEDRRVRPTSSGDLYYIGT JQ 6129 gb: JQ001776: 6 MSNKRTTVLIIISYTLFYLNNAAIVGFDFDKLN 3 24 57 001 - 129- KIGVVQGRVLNYKIKGDPMTKDLVLKFIPNIV 776 8166 8166|Organism: NITECVREPLSRYNETVRRLLLPIHNMLGLYL Cedar NNTNAKMTGLMIAGVIMGGIAIGIATAAQITA virus|Strain GFALYEAKKNTENIQKLTDSIMKTQDSIDKLT Name: CG1a|Pr DSVGTSILILNKLQTYINNQLVPNLELLSCRQN otein KOEFDLMLTKYLVDLMTVIGPNINNPVNKDM Name: fusion TIQSLSLLFDGNYDIMMSELGYTPQDFLDLIES glycoprotein|G KSITGQIIYVDMENLYVVIRTYLPTHEVPDAQI ene Symbol: F YEFNKITMSSNGGEYLSTIPNFILIRGNYMSNI DVATCYMTKASVICNQDYSLPMSQNLRSCYQ GETEYCPVEAVIASHSPRFALTNGVIFANCINT ICRCQDNGKTITQNINQFVSMIDNSTCNDVMV DKFTIKVGKYMGRKDINNINIQIGPQIIIDKVD LSNEINKMNQSLKDSIFYLREAKRILDSVNISLI SPSVQLFLIIISVLSFIILLIIIVYLYCKSKHSYKY NKFIDDPDYYNDYKRERINGKASKSNNIYYV GD NC_ 5950 gb: NC_025352: MALNKNMFSSLFLGYLLVYATTVQSSIHYDS 2 25 60 02 - 5950- LSKVGVIKGLTYNYKIKGSPSTKLMVVKLIPNI 535 8712 8712|Organism: DSVKNCTQKQYDEYKNLVRKALEPVKMAID 2 Mojiang TMLNNVKSGNNKYRFAGAIMAGVALGVATA virus|Strain ATVTAGIALHRSNENAQAIANMKSAIQNTNE Name: Tonggua AVKQLQLANKQTLAVIDTIRGEINNNIIPVINQ n1|Protein LSCDTIGLSVGIRLTQYYSEIITAFGPALQNPV Name: fusion NTRITIQAISSVFNGNFDELLKIMGYTSGDLYE protein|Gene ILHSELIRGNIIDVDVDAGYIALEIEFPNLTLVP Symbol: F NAVVQELMPISYNIDGDEWVTLVPRFVLTRTT LLSNIDTSRCTITDSSVICDNDYALPMSHELIG CLQGDTSKCAREKVVSSYVPKFALSDGLVYA NCLNTICRCMDTDTPISQSLGATVSLLDNKRC SVYQVGDVLISVGSYLGDGEYNADNVELGPPI VIDKIDIGNQLAGINQTLQEAEDYIEKSEEFLK GVNPSIITLGSMVVLYIFMILIAIVSVIALVLSIK LTVKGNVVRQQFTYTQHVPSMENINYVSH NC_ 6865 gb: NC_025256: MKKKTDNPTISKRGHNHSRGIKSRALLRETDN 2 26 58 02 - 6865- YSNGLIVENLVRNCHHPSKNNLNYTKTQKRD 525 8853 8853|Organism: STIPYRVEERKGHYPKIKHLIDKSYKHIKRGKR 6 Bat RNGHNGNIITIILLLILILKTQMSEGAIHYETLS Paramyxovirus KIGLIKGITREYKVKGTPSSKDIVIKLIPNVTGL Eid_he1/GH- NKCTNISMENYKEQLDKILIPIINNIIELYANSTK M74a/GHA/20 SAPGNARFAGVIIAGVALGVAAAAQITAGIAL 09|Strain HEARQNAERINLLKDSISATNNAVAELQEATG Name: BatPV/E GIVNVITGMQDYINTNLVPQIDKLQCSQIKTA id_he1/GH- LDISLSQYYSEILTVFGPNLQNPVTTSMSIQAIS M74a/GHA/20 QSFGGNIDLLLNLLGYTANDLLDLLESKSITG 09|Protein QITYINLEHYFMVIRVYYPIMTTISNAYVQELI Name: fusion KISFNVDGSEWVSLVPSYILIRNSYLSNIDISEC protein|Gene LITKNSVICRHDFAMPMSYTLKECLTGDTEKC Symbol: F PREAVVTSYVPRFAISGGVIYANCLSTTCQCY QTGKVIAQDGSQTLMMIDNQTCSIVRIEEILIS TGKYLGSQEYNTMHVSVGNPVFTDKLDITSQI SNINQSIEQSKFYLDKSKAILDKINLNLIGSVPI SILFIIAILSLILSIITFVIVMIIVRRYNKYTPLINS DPSSRRSTIQDVYIIPNPGEHSIRSAARSIDRDR D

In some embodiments, the F protein is encoded by a nucleotide sequence that encodes the sequence set forth by any one of SEQ ID NOs: 1, 2, 17, 24, 25, 26 or 57-60 or is a functionally active variant or a biologically active portion thereof that has a sequence that is at least at or about 80%, at least at or about 85%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% identical to any one of SEQ ID NOS: 1, 2, 17, 24, 25, 26 or 57-60. In particular embodiments, the F protein or the functionally active variant or biologically active portion thereof retains fusogenic activity in conjunction with a Henipavirus G protein, such as a G protein set forth in Section I.A (e.g. NiV-G or HeV-G). Fusogenic activity includes the activity of the F protein in conjunction with a Henipavirus G protein to promote or facilitate fusion of two membrane lumens, such as the lumen of the targeted lipid particle having embedded in its lipid bilayer a henipavirus F and G protein, and a cytoplasm of a target cell, e.g. a cell that contains a surface receptor or molecule that is recognized or bound by the targeted envelope protein. In some embodiments, the F protein and G protein are from the same Henipavirus species (e.g. NiV-G and NiV-F). In some embodiments, the F protein and G protein are from different Henipavirus species (e.g. NiV-G and HeV-F). In particular embodiments, the F protein of the functionally active variant or biologically active portion retains the cleavage site cleaved by cathepsin L (e.g. corresponding to the cleavage site between amino acids 109-110 of SEQ ID NO:1).

In particular embodiments, the F protein has the sequence of amino acids set forth in SEQ ID NO: 1, SEQ ID NO:2, SEQ ID NO:17, SEQ ID NO: 24, SEQ ID NO:25, SEQ ID NO: 26, SEQ ID NO: 57, SEQ ID NO: 57, SEQ ID NO: 58, SEQ ID NO: 59, or SEQ ID NO: 60 or is a functionally active variant thereof or a biologically active portion thereof that retains fusogenic activity. In some embodiments, the functionally active variant comprises an amino acid sequence having at least at or about 80%, at least at or about 85%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 1, SEQ ID NO:2, SEQ ID NO:17, SEQ ID NO: 24, SEQ ID NO:25, SEQ ID NO: 26, SEQ ID NO: 57, SEQ ID NO: 57, SEQ ID NO: 58, SEQ ID NO: 59, or SEQ ID NO: 60 and retains fusogenic activity in conjunction with a Henipavirus G protein (e.g., NiV-G or HeV-G). In some embodiments, the biologically active portion has an amino acid sequence having at least at or about 80%, at least at or about 85%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 1, SEQ ID NO:2, SEQ ID NO:17, SEQ ID NO: 24, SEQ ID NO:25, SEQ ID NO: 26, SEQ ID NO: 57, SEQ ID NO: 57, SEQ ID NO: 58, SEQ ID NO: 59, or SEQ ID NO: 60 and retains fusogenic activity in conjunction with a Henipavirus G protein (e.g., NiV-G or HeV-G).

Reference to retaining fusogenic activity includes activity (in conjunction with a Henipavirus G protein) that between at or about 10% and at or about 150% or more of the level or degree of binding of the corresponding wild-type F protein, such as set forth in SEQ ID NO: 1, SEQ ID NO:2, SEQ ID NO:17, SEQ ID NO: 24, SEQ ID NO:25, SEQ ID NO: 26, SEQ ID NO: 57, SEQ ID NO: 57, SEQ ID NO: 58, SEQ ID NO: 59, or SEQ ID NO: 60, such as at least or at least about 10% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 15% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 20% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 25% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 30% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 35% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 40% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 45% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 50% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 55% of the level or degree of fusogenic activity of the corresponding wild-type f protein, such as at least or at least about 60% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 65% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 70% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 75% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 80% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 85% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 90% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 95% of the level or degree of fusogenic activity of the corresponding wild-type F protein, such as at least or at least about 100% of the level or degree of fusogenic activity of the corresponding wild-type F protein, or such as at least or at least about 120% of the level or degree of fusogenic activity of the corresponding wild-type F protein.

In some embodiments, the F protein is a mutant F protein that is a functionally active fragment or a biologically active portion containing one or more amino acid mutations, such as one or more amino acid insertions, deletions, substitutions or truncations. In some embodiments, the mutations described herein relate to amino acid insertions, deletions, substitutions or truncations of amino acids compared to a reference F protein sequence. In some embodiments, the reference F protein sequence is the wild-type sequence of an F protein or a biologically active portion thereof. In some embodiments, the mutant F protein or the biologically active portion thereof is a mutant of a wild-type Hendra (Hey) virus F protein, a Nipah (NiV) virus F-protein, a Cedar (CedPV) virus F protein, a Mojiang virus F protein or a bat Paramyxovirus F protein. In some embodiments, the wild-type F protein is encoded by a sequence of nucleotides that encodes any one of SEQ ID NO: 1, 2, 17, 24, 25, 26, or 57-60.

In some embodiments, the mutant F protein is a biologically active portion of a wild-type F protein that is an N-terminally and/or C-terminally truncated fragment. In some embodiments, the mutant F protein or the biologically active portion of a wild-type F protein thereof comprises one or more amino acid substitutions. In some embodiments, the mutations described herein can improve transduction efficiency. In some embodiments, the mutations described herein can increase fusogenic capacity. Exemplary mutations include any as described, see e.g. Khetawat and Broder 2010 Virology Journal 7:312; Witting et al. 2013 Gene Therapy 20:997-1005; published international; patent application No. WO/2013/148327.

In some embodiments, the mutant F protein is a biologically active portion that is truncated and lacks up to 20 contiguous amino acid residues at or near the C-terminus of the wild-type F protein, such as a wild-type F protein encoded by a sequence of nucleotides encoding the F protein set forth in any one of SEQ ID NOS: 1, 17, 24, 25 or 26. In some embodiments, the mutant F protein is truncated and lacks up to 19 contiguous amino acids, such as up to 18, 17, 16, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, or 1 contiguous amino acids at the C-terminus of the wild-type F protein.

In some embodiments, the F protein or the functionally active variant or biologically active portion thereof comprises an F1 subunit or a fusogenic portion thereof. In some embodiments, the F1 subunit is a proteolytically cleaved portion of the F0 precursor. In some embodiments, the F0 precursor is inactive. In some embodiments, the cleavage of the F0 precursor forms a disulfide-linked F1+F2 heterodimer. In some embodiments, the cleavage exposes the fusion peptide and produces a mature F protein. In some embodiments, the cleavage occurs at or around a single basic residue. In some embodiments, the cleavage occurs at Arginine 109 of NiV-F protein. In some embodiments, cleavage occurs at Lysine 109 of the Hendra virus F protein.

In some embodiments, the F protein is a wild-type Nipah virus F (NiV-F) protein or is a functionally active variant or biologically active portion thereof. In some embodiments, the F₀ precursor is encoded by a sequence of nucleotides encoding the sequence set forth in SEQ ID NO: 1. The encoding nucleic acid can encode a signal peptide sequence that has the sequence MVVILDKRCY CNLLILILMI SECSVG (SEQ ID NO: 34). In some embodiments, the F protein has the sequence set forth in SEQ ID NO:2. In some examples, the F protein is cleaved into an F1 subunit comprising the sequence set forth in SEQ ID NO:4 and an F2 subunit comprising the sequence set forth in SEQ ID NO: 3.

In some embodiments, the F protein is a NiV-F protein that is encoded by a sequence of nucleotides encoding the sequence set forth in SEQ ID NO:1, or is a functionally active variant or biologically active portion thereof that has an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at or about 86%, at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 1. In some embodiments, the NiV-F-protein has the sequence of set forth in SEQ ID NO: 2, or is a functionally active variant or a biologically active portion thereof that has an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at or about 86%, at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 2. In particular embodiments, the F protein or the functionally active variant or biologically active portion thereof retains the cleavage site cleaved by cathepsin L (e.g. corresponding to the cleavage site between amino acids 109-110 of SEQ ID NO:1).

In some embodiments, the F protein or the functionally active variant or the biologically active portion thereof includes an F1 subunit that has the sequence set forth in SEQ ID NO: 4, or an amino acid sequence having, at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at or about 86%, at least at or about 87%, at least at or about 88%, or at least at or about 89% at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:4.

In some embodiments, the F protein or the functionally active variant or biologically active portion thereof includes an F2 subunit that has the sequence set forth in SEQ ID NO: 3, or an amino acid sequence having, at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at or about 86%, at least at or about 87%, at least at or about 88%, or at least at or about 89% at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:3.

In some embodiments, the F protein is a mutant NiV-F protein that is a biologically active portion thereof that is truncated and lacks up to 20 contiguous amino acid residues at or near the C-terminus of the wild-type NiV-F protein (e.g. set forth SEQ ID NO:2). In some embodiments, the mutant NiV-F protein comprises an amino acid sequence set forth in SEQ ID NO:5. In some embodiments, the mutant NiV-F protein has a sequence that has at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 5. In some embodiments, the mutant F protein contains an F1 protein that has the sequence set forth in SEQ ID NO:6. In some embodiments, the mutant F protein has a sequence that has at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 6.

In some embodiments, the F protein is a mutant NiV-F protein that is a biologically active portion thereof that comprises a 20 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2); and a point mutation on an N-linked glycosylation site. In some embodiments, the mutant NiV-F protein comprises an amino acid sequence set forth in SEQ ID NO: 7. In some embodiments, the mutant NiV-F protein has a sequence that has at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 7.

In some embodiments, the F protein is a mutant NiV-F protein that is a biologically active portion thereof that comprises a 22 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2). In some embodiments, the NiV-F protein is encoded by a nucleotide sequence that encodes the sequence set forth in SEQ ID NO: 8. In some embodiments, the NiV-F proteins is encoded by a nucleotide sequence that encodes sequence having at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 8. In particular embodiments, the variant F protein is a mutant Niv-F protein that has the sequence of amino acids set forth in SEQ ID NO:23. In some embodiments, the NiV-F proteins is encoded by a a sequence having at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 23.

C. Lipid Bilayer

In some embodiments, the targeted lipid particle includes a naturally derived bilayer of amphipathic lipids that encloses lumen or cavity. In some embodiments, the targeted lipid particle comprises a lipid bilayer as the outermost surface. In some embodiments, the lipid bilayer encloses a lumen. In some embodiments, the lumen is aqueous. In some embodiments, the lumen is in contact with the hydrophilic head groups on the interior of the lipid bilayer. In some embodiments, the lumen is a cytosol. In some embodiments, the cytosol contains cellular components present in a source cell. In some embodiments, the cytosol does not contain components present in a source cell. In some embodiments, the lumen is a cavity. In some embodiments, the cavity contains an aqueous environment. In some embodiments, the cavity does not contain an aqueous environment.

In some aspects, the lipid bilayer is derived from a source cell during a process to produce a lipid-containing particle. Exemplary methods for producing lipid-containing particles are provided in Section I.E. In some embodiments, the lipid bilayer includes membrane components of the cell from which the lipid bilayer is produced, e.g., phospholipids, membrane proteins, etc. In some embodiments, the lipid bilayer includes a cytosol that includes components found in the cell from which the micro-vesicle is produced, e.g., solutes, proteins, nucleic acids, etc., but not all of the components of a cell, e.g., they lack a nucleus. In some embodiments, the lipid bilayer is considered to be exosome-like. The lipid bilayer may vary in size, and in some instances have a diameter ranging from 30 and 300 nm, such as from 30 and 150 nm, and including from 40 to 100 nm.

In some embodiments, the lipid bilayer is a viral envelope. In some embodiments, the viral envelope is obtained from a source cell. In some embodiments, the viral envelope is obtained by the viral capsid from the source cell plasma membrane. In some embodiments, the lipid bilayer is obtained from a membrane other than the plasma membrane of a host cell. In some embodiments, the viral envelope lipid bilayer is embedded with viral proteins, including viral glycoproteins.

In other aspects, the lipid bilayer includes synthetic lipid complex. In some embodiments, the synthetic lipid complex is a liposome. In some embodiments, the lipid bilayer is a vesicular structure characterized by a phospholipid bilayer membrane and an inner aqueous medium. In some embodiments, the lipid bilayer has multiple lipid layers separated by aqueous medium. In some embodiments, the lipid bilayer forms spontaneously when phospholipids are suspended in an excess of aqueous solution. In some examples, the lipid components undergo self-rearrangement before the formation of closed structures and entrap water and dissolved solutes between the lipid bilayers.

In some embodiments, a targeted envelope protein and fusogen, such as any described above including any that are exogenous or overexpressed relative to the source cell, is disposed in the lipid bilayer.

In some embodiments, the targeted lipid particle comprises several different types of lipids. In some embodiments, the lipids are amphipathic lipids. In some embodiments, the amphipathic lipids are phospholipids. In some embodiments, the phospholipids comprise phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol, and phosphatidylserine. In some embodiments, the lipids comprise phospholipids such as phosphocholines and phosphoinositols. In some embodiments, the lipids comprise DMPC, DOPC, and DSPC.

In some embodiments, the bilayer may be comprised of one or more lipids of the same or different type. In some embodiments, the source cell comprises a cell selected from CHO cells, BHK cells, MDCK cells, C3H 10T1/2 cells, FLY cells, Psi-2 cells, BOSC 23 cells, PA317 cells, WEHI cells, COS cells, BSC 1 cells, BSC 40 cells, BMT 10 cells, VERO cells, W138 cells, MRCS cells, A549 cells, HT1080 cells, 293 cells, 293T cells, B-50 cells, 3T3 cells, NIH3T3 cells, HepG2 cells, Saos-2 cells, Huh7 cells, HeLa cells, W163 cells, 211 cells, and 211A cells.

D. Exogenous Agent

In embodiments, the targeted lipid particle, such as a lentiviral vector, further comprises an agent that is exogenous relative to the source cell (hereinafter also called “cargo” or “payload”). In some embodiments, the exogenous agent is a protein or a nucleic acid (e.g., a DNA, a chromosome (e.g. a human artificial chromosome), an RNA, e.g., an mRNA or miRNA). In some embodiments, the exogenous agent is a nucleic acid that encodes a protein. The protein can be any protein as is desired for targeted delivery to a target cell. In some embodiments, the protein is a therapeutic agent or a diagnostic agent. In some embodiments, the protein is an antigen receptor for targeting cells expressed by or associated with a disease or condition, for instance a chimeric antigen receptor (CAR) or a T cell receptor (TCR). Reference to the coding sequence of a nucleic acid encoding the protein also is referred to herein as a payload gene. In some embodiments, the exogenous agent or the nucleic acid encoding the exogenous agent are present in the lumen of the non-cell particle.

In some embodiments, the exogenous agent or cargo comprises or encodes a cytosolic protein. In some embodiments the exogenous agent or cargo comprises or encodes a membrane protein. In some embodiments, the exogenous agent or cargo comprises or encodes a therapeutic agent. In some embodiments, the therapeutic agent is chosen from one or more of a protein, e.g., an enzyme, a transmembrane protein, a receptor, an antibody; a nucleic acid, e.g., DNA, a chromosome (e.g. a human artificial chromosome), RNA, mRNA, siRNA, miRNA, or a small molecule.

In embodiments, the exogenous agent is present at least, or no more than, 10, 20, 50, 100, 200, 500, 1,000, 2,000, 5,000, 10,000, 20,000, 50,000, 100,000, 200,000, 500,000, 1,000,000, 5,000,000, 10,000,000, 50,000,000, 100,000,000, 500,000,000, or 1,000,000,000 copies. In embodiments, the targeted lipid particle has an altered, e.g., increased or decreased level of one or more endogenous molecule, e.g., protein or nucleic acid (e.g., in some embodiments, endogenous relative to the source cell, and in some embodiments, endogenous relative to the target cell), e.g., due to treatment of the source cell, e.g., mammalian source cell with a siRNA or gene editing enzyme. In embodiments, the endogenous molecule is present at least, or no more than, 10, 20, 50, 100, 200, 500, 1,000, 2,000, 5,000, 10,000, 20,000, 50,000, 100,000, 200,000, 500,000, 1,000,000, 5,000,000, 10,000,000, 50,000,000, 100,000,000, 500,000,000, or 1,000,000,000 copies. In embodiments, the endogenous molecule (e.g., an RNA or protein) is present at a concentration of at least 1, 2, 3, 4, 5, 10, 20, 50, 100, 500, 10³, 5.0×10³, 10⁴, 5.0×10⁴, 10⁵, 5.0×10⁵, 10⁶, 5.0×10⁶, 1.0×10⁷, 5.0×10⁷, or 1.0×10⁸, greater than its concentration in the source cell. In embodiments, the endogenous molecule (e.g., an RNA or protein) is present at a concentration of at least 1, 2, 3, 4, 5, 10, 20, 50, 100, 500, 10³, 5.0×10³, 10⁴, 5.0×10⁴, 10⁵, 5.0×10⁵, 10⁶, 5.0×10⁶, 1.0×10⁷, 5.0×10⁷, or 1.0×10⁸ less than its concentration in the source cell.

In some embodiments, the targeted lipid particle delivers to a target cell at least 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 95%, 96%, 97%, 98%, or 99% of the cargo (e.g., a therapeutic agent, e.g., an exogenous therapeutic agent) comprised by the fusosome. In some embodiments, the targeted lipid particle that fuses with the target cell(s) delivers to the target cell an average of at least 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 95%, 96%, 97%, 98%, or 99% of the cargo (e.g., a therapeutic agent, e.g., an exogenous therapeutic agent) comprised by the lipid particles that fuse with the target cell(s). In some embodiments, the targeted lipid particle composition delivers to a target tissue at least 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 95%, 96%, 97%, 98%, or 99% of the cargo (e.g., a therapeutic agent, e.g., an exogenous therapeutic agent) comprised by the targeted lipid particle compositions.

In some embodiments, the exogenous agent or cargo is not expressed naturally in the cell from which the targeted lipid particle is derived. In some embodiments, the exogenous agent or cargo is expressed naturally in the cell from which the targeted lipid particle is derived. In some embodiments, the exogenous agent or cargo is loaded into the targeted lipid particle via expression in the cell from which the lipid particle is derived (e.g. expression from DNA or mRNA introduced via transfection, transduction, or electroporation). In some embodiments, the exogenous agent or cargo is expressed from DNA integrated into the genome or maintained episosomally. In some embodiments, expression of the exogenous agent or cargo is constitutive. In some embodiments, expression of the exogenous agent or cargo is induced. In some embodiments, expression of the exogenous agent or cargo is induced immediately prior to generating the targeted lipid particle. In some embodiments, expression of the exogenous agent or cargo is induced at the same time as expression of the fusogen.

In some embodiments, the exogenous agent or cargo is loaded into the lipid particle via electroporation into the lipid particle itself or into the cell from which the fusosome is derived. In some embodiments, the exogenous agent or cargo is loaded into the lipid particle via transfection (e.g., of a DNA or mRNA encoding the cargo) into the lipid particle itself or into the cell from which the lipid particle is derived.

In some embodiments, the exogenous agent or cargo may include one or more nucleic acid sequences, one or more polypeptides, a combination of nucleic acid sequences and/or polypeptides, one or more organelles, and any combination thereof. In some embodiments, the exogenous agent or cargo may include one or more cellular components. In some embodiments, the exogenous agent or cargo includes one or more cytosolic and/or nuclear components.

In some embodiments, the exogenous agent or cargo includes a nucleic acid, e.g., DNA, nDNA (nuclear DNA), mtDNA (mitochondrial DNA), protein coding DNA, gene, operon, chromosome, genome, transposon, retrotransposon, viral genome, intron, exon, modified DNA, mRNA (messenger RNA), tRNA (transfer RNA), modified RNA, microRNA, siRNA (small interfering RNA), tmRNA (transfer messenger RNA), rRNA (ribosomal RNA), mtRNA (mitochondrial RNA), snRNA (small nuclear RNA), small nucleolar RNA (snoRNA), SmY RNA (mRNA trans-splicing RNA), gRNA (guide RNA), TERC (telomerase RNA component), aRNA (antisense RNA), cis-NAT (Cis-natural antisense transcript), CRISPR RNA (crRNA), IncRNA (long noncoding RNA), piRNA (piwi-interacting RNA), shRNA (short hairpin RNA), tasiRNA (trans-acting siRNA), eRNA (enhancer RNA), satellite RNA, pcRNA (protein coding RNA), dsRNA (double stranded RNA), RNAi (interfering RNA), circRNA (circular RNA), reprogramming RNAs, aptamers, and any combination thereof. In some embodiments, the nucleic acid is a wild-type nucleic acid. In some embodiments, the protein is a mutant nucleic acid. In some embodiments the nucleic acid is a fusion or chimera of multiple nucleic acid sequences.

In some embodiments, the exogenous agent or cargo may include a nucleic acid. For example, the exogenous agent or cargo may comprise RNA to enhance expression of an endogenous protein, or a siRNA or miRNA that inhibits protein expression of an endogenous protein. For example, the endogenous protein may modulate structure or function in the target cells. In some embodiments, the cargo may include a nucleic acid encoding an engineered protein that modulates structure or function in the target cells. In some embodiments, the exogenous agent or cargo is a nucleic acid that targets a transcriptional activator that modulate structure or function in the target cells.

In some embodiments, the exogenous agent or cargo is or encodes a polypeptide, e.g., enzymes, structural polypeptides, signaling polypeptides, regulatory polypeptides, transport polypeptides, sensory polypeptides, motor polypeptides, defense polypeptides, storage polypeptides, transcription factors, antibodies, cytokines, hormones, catabolic polypeptides, anabolic polypeptides, proteolytic polypeptides, metabolic polypeptides, kinases, transferases, hydrolases, lyases, isomerases, ligases, enzyme modulator polypeptides, protein binding polypeptides, lipid binding polypeptides, membrane fusion polypeptides, cell differentiation polypeptides, epigenetic polypeptides, cell death polypeptides, nuclear transport polypeptides, nucleic acid binding polypeptides, reprogramming polypeptides, DNA editing polypeptides, DNA repair polypeptides, DNA recombination polypeptides, transposase polypeptides, DNA integration polypeptides, targeted endonucleases (e.g. Zinc-finger nucleases, transcription-activator-like nucleases (TALENs), cas9 and homologs thereof), recombinases, and any combination thereof. In some embodiments the protein targets a protein in the cell for degradation. In some embodiments the protein targets a protein in the cell for degradation by localizing the protein to the proteasome. In some embodiments, the protein is a wild-type protein. In some embodiments, the protein is a mutant protein. In some embodiments the protein is a fusion or chimeric protein.

In some embodiments, the exogenous agent or cargo is a small molecule, e.g., ions (e.g. Ca²⁺, Cl-, Fe²⁺), carbohydrates, lipids, reactive oxygen species, reactive nitrogen species, isoprenoids, signaling molecules, heme, polypeptide cofactors, electron accepting compounds, electron donating compounds, metabolites, ligands, and any combination thereof. In some embodiments the small molecule is a pharmaceutical that interacts with a target in the cell. In some embodiments the small molecule targets a protein in the cell for degradation. In some embodiments the small molecule targets a protein in the cell for degradation by localizing the protein to the proteasome. In some embodiments that small molecule is a proteolysis targeting chimera molecule (PROTAC).

In some embodiments, the exogenous agent or cargo includes a mixture of proteins, nucleic acids, or metabolites, e.g., multiple polypeptides, multiple nucleic acids, multiple small molecules; combinations of nucleic acids, polypeptides, and small molecules; ribonucleoprotein complexes (e.g. Cas9-gRNA complex); multiple transcription factors, multiple epigenetic factors, reprogramming factors (e.g. Oct4, Sox2, cMyc, and Klf4); multiple regulatory RNAs; and any combination thereof.

In some embodiments, the exogenous agent or cargo includes one or more organelles, e.g., chondrisomes, mitochondria, lysosomes, nucleus, cell membrane, cytoplasm, endoplasmic reticulum, ribosomes, vacuoles, endosomes, spliceosomes, polymerases, capsids, acrosome, autophagosome, centriole, glycosome, glyoxysome, hydrogenosome, melanosome, mitosome, myofibril, cnidocyst, peroxisome, proteasome, vesicle, stress granule, networks of organelles, and any combination thereof.

In some embodiments, the exogenous agent is or encodes a cytosolic protein, e.g., a protein that is produced in the recipient cell and localizes to the recipient cell cytoplasm. In some embodiments, the exogenous agent is or encodes a secreted protein, e.g., a protein that is produced and secreted by the recipient cell. In some embodiments, the exogenous agent is or encodes a nuclear protein, e.g., a protein that is produced in the recipient cell and is imported to the nucleus of the recipient cell. In some embodiments, the exogenous agent is or encodes an organellar protein (e.g., a mitochondrial protein), e.g., a protein that is produced in the recipient cell and is imported into an organelle (e.g., a mitochondrial) of the recipient cell. In some embodiments, the protein is a wild-type protein or a mutant protein. In some embodiments the protein is a fusion or chimeric protein.

In some embodiments, the exogenous agent is capable of being delivered to a hepatocyte or liver cell. In some embodiments, the exogenous agents or cargo can be delivered to treat a disease or disorder in a hepatocyte or liver cell.

In some embodiments, the exogenous agent is encoded by a gene from among OTC, CPS1, NAGS, BCKDHA, BCKDHB, DBT, DLD, MUT, MMAA, MMAB, MMACHC, MMADHC, MCEE, PCCA, PCCB, UGT1A1, ASS1, PAH, PAL, ATP8B1, ABCB11, ABCB4, TJP2, IVD, GCDH, ETFA, ETFB, ETFDH, ASL, D2HGDH, HMGCL, MCCC1, MCCC2, ABCD4, HCFC1, LNBRD1, ARG1, SLC25A15, SLC25A13, ALAD, CPDX, HMBS, PPDX, BTD, HLCS, PC, SLC7A7, CPT2, ACADM, ACADS, ACADVL, AGL, G6PC, GBE1, PHKA1, PHKA2, PHKB, PHKG2, SLC37A4, PMM2, CBS, FAH, TAT, GALT, GALK1, GALE, G6PD, SLC3A1, SLC7A9, MTHFR, MTR, MTRR, ATP7B, HPRT1, HJV, HAMP, JAG1, TTR, AGXT, LIPA, SERPING1, HSD17B4, UROD, HFE, LPL, GRHPR, HOGA1, LDLR, ACAD8, ACADSB, ACAT1, ACSF3, ASPA, AUH, DNAJC19, ETHE1, FBP1, FTCD, GSS, HIBCH, IDH2, L2HGDH, MLYCD, OPA3, OPLAH, OXCT1, POLG, PPM1K, SERAC1, SLC25A1, SUCLA2, SUCLG1, TAZ, AGK, CLPB, TMEM70, ALDH18A1, OAT, CASA, GLUD1, GLUL, UMPS, SLC22A5, CPT1A, HADHA, HADH, SLC52A1, SLC52A2, SLC52A3, HADHB, GYS2, PYGL, SLC2A2, ALG1, ALG2, ALG3, ALG6, ALG8, ALG9, ALG11, ALG12, ALG13, ATP6V0A2, B3GLCT, CHST14, COG1, COG2, COG4, COG5, COG6, COG7, COG8, DOLK, DHDDS, DPAGT1, DPM1, DPM2, DPM3, G6PC3, GFPT1, GMPPA, GMPPB, MAGT1, MAN1B1, MGAT2, MOGS, MPDU1, MPI, NGLY1, PGM1, PGM3, RFT1, SEC23B, SLC35A1, SLC35A2, SLC35C1, SSR4, SRD5A3, TMEM165, TRIP11, TUSC3, ALG14, B4GALT1, DDOST, NUS1, RPN2, SEC23A, SLC35A3, ST3GAL3, STT3A, STT3B, AGA, ARSA, ARSB, ASAH1, ATP13A2, CLN3, CLNS, CLN6, CLN8, CTNS, CTSA, CTSD, CTSF, CTSK, DNAJCS, FUCA1, GAA, GALC, GALNS, GLA, GLB1, GM2A, GNPTAB, GNPTG, GNS, GRN, GUSB, HEXA, HEXB, HGSNAT, HYAL1, IDS, IDUA, KCTD7, LAMP2, MAN2B1, MANBA, MCOLN1, MFSD8, NAGA, NAGLU, NEU1 NPC1, NPC2, SGSH, PPT1, PSAP, SLC17A5, SMPD1, SUMF1, TPP1, AHCY, GNMT, MAT1A, GCH1, PCBD1, PTS, QDPR, SPR, DNAJC12, ALDH4A1, PRODH, HPD, GBA, HGD, AMN, CD320, CUBN, GIF, TCN1, TCN2, PREPL, PHGDH, PSAT1, PSPH, AMT, GCSH, GLDC, LIAS, NFU1, SLC6A9, SLC2A1, ATP7A, AP1S1, CP, SLC33A1, PEX7 PHYH, AGPS, GNPAT, ABCD1, ACOX1, PEX1, PEX2, PEX3, PEXS, PEX6, PEX10, PEX12, PEX13, PEX14, PEX16, PEX19, PEX26, AMACR, ADA, ADSL, AMPD1, GPHN, MOCOS, MOCS1, PNP, XDH, SUOX, OGDH, SLC25A19, DHTKD1, SLC13A5, FH, DLAT, MPC1, PDHA1, PDHB, PDHX, PDP1, ABCC2, SLCO1B1, SLCO1B3, HFE2, ADAMTS13, PYGM, COL1A2, TNFRSF11B, TSC1, TSC2, DHCR7, PGK1, VLDLR, KYNU, F5, C3, COL4A1, CFH, SLC12A2, GK, SFTPC, CRTAP, P3H1, COL7A1, PKLR, TALDO1, TF, EPCAM, VHL, GC, SERPINA1, ABCC6, F8, F9, ApoB, PCSK9, LDLRAP1, ABCGS, ABCG8, LCAT, SPINKS, or GNE.

In some embodiments, the exogenous agent is encoded by a gene from among OTC, CPS1, NAGS, BCKDHA, BCKDHB, DBT, DLD, MUT, MMAA, MMAB, MMACHC, MMADHC, MCEE, PCCA, PCCB, UGT1A1, ASS1, PAL, PAH, ATP8B1, ABCB11, ABCB4, TJP2, IVD, GCDH, ETFA, ETFB, ETFDH, ASL, D2HGDH, HMGCL, MCCC1, MCCC2, ABCD4, HCFC1, LMBRD1, ARG1, SLC25A15, SLC25A13, ALAD, CPDX, HMBS, PPDX, BTD, HLCS, PC, SLC7A7, CPT2, ACADM, ACADS, ACADVL, AGL, G6PC, GBE1, PHKA1, PHKA2, PHKB, PHKG2, SLC37A4, PMM2, CBS, FAH, TAT, GALT, GALK1, GALE, G6PD, SLC3A1, SLC7A9, MTHFR, MTR, MTRR, ATP7B, HPRT1, HJV, HAMP, JAG1, TTR, AGXT, LIPA, SERPING1, HSD17B4, UROD, HFE, LPL, GRHPR, HOGA1, or LDLR. In some embodiments, the exogenous agent is the enzyme phenylalanine ammonia lyase (PAL).

In some embodiments, the exogenous agents or cargo can be delivered to treat and disease or indication listed in Table 5. In some embodiments, the indications are specific for a liver cell or hepatocyte.

In some embodiments, the exogenous agent comprises a protein of Table 5 below. In some embodiments, the exogenous agent comprises the wild-type human sequence of any of the proteins of Table 5, a functional fragment thereof (e.g., an enzymatically active fragment thereof), or a functional variant thereof. In some embodiments, the exogenous agent comprises an amino acid sequence having at least 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98%, or 99%, identity to an amino acid sequence of Table 5, e.g., a Uniprot Protein Accession Number sequence of column 4 of Table 5 or an amino acid sequence of column 5 of Table 5. In some embodiments, the payload gene encoding an exogenous agent encodes an amino acid sequence having at least 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98%, or 99%, identity to an amino acid sequence of Table 5. In some embodiments, the payload gene encoding an exogenous agent has a nucleic acid sequence having at least 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98%, or 99%, identity to a nucleic acid sequence of Table 5, e.g., an Ensemble Gene Accession Number of column 3 of Table 5.

TABLE 5 The first column lists exogenous agents that can be delivered to treat the indications in the sixth column, according to the methods and uses herein. Each Uniprot accession number of Table 5 is herein incorporated by reference in its entirety. Ensembl Amino Acid Gene(s) Sequence Accession Uniprot (first Uniprot Entrez Number Protein(s) Accession Accession (ENSG0000 + Accession Number) Gene Number number shown) Number SEQ ID NO Disease/Disorder Category OTC 5009 0036473 P00480 61 ornithine Urea cycle disorder transcarbamylase (OTC) deficiency CPS1 1373 0021826 P31327, 62 carbamoyl Urea cycle disorder Q6PEK7, phosphate B7ZAW0, synthetase I A0A024R454 (CPSI) deficiency NAGS 162417 0161653 Q8N159, 63 N-acetylglutamate Urea cycle disorder Q2NKP2 synthase (NAGS) deficiency BCKDHA 593 0248098 A0A024R0K3, 64 maple syrup urine Organic acidemia P12694, disease (MSUD); Q59EI3 Classic Maple Syrup Urine Disease (CMSUD) BCKDHB 594 0083123 A0A140VKB3, 65 maple syrup urine Organic acidemia P21953, disease (MSUD); B4E2N3, Classic Maple B7ZB80 Syrup Urine Disease (CMSUD) DBT 1629 0137992 P11182 66 maple syrup urine Organic acidemia disease (MSUD); Classic Maple Syrup Urine Disease (CMSUD) DLD 1738 0091140 A0A024R713, 67 maple syrup urine Urea cycle disorder P09622, disease (MSUD) E9PEX6 Dihydrolipoamide dehydrogenase deficiency MUT 4594 0146085 A0A024RD82, 68 methylmalonic Organic acidemia B2R6K1, acidemia due to P22033 methylmalonyl- CoA mutase deficiency MMAA 166785 0151611 Q8IVH4 69 cobalamin A Organic acidemia deficiency (methylmalonic acidemia) MMAB 326625 0139428 Q96EY8 70 cobalamin B Organic acidemia deficiency (methylmalonic acidemia) MMACHC 25974 0132763 A0A0C4DGU2, 71 cobalamin C Organic acidemia Q9Y4U1 deficiency (methylmalonic acidemia); Methylmalonic Acidemia with Homocystinuria MMADHC 27249 0168288 Q9H3L0 72 cobalamin D Organic acidemia deficiency (methylmalonic acidemia); Methylmalonic Acidemia with Homocystinuria; Homocystinuria; Cobalamin C Deficiency MCEE 84693 0124370 Q96PE7 73 methylmalonic Organic acidemia acidemia; Cobalamin D Deficiency PCCA 5095 0175198 P05165 74 propionic acidemia Organic acidemia PCCB 5096 0114054 P05166 75 propionic acidemia Organic acidemia UGT1A1 54658 0241635 P22309, 76 Crigler-Najjar Q5DT03 syndrome type 1 Crigler-Najjar syndrome type 2, Gilbert syndrome ASS1 445 0130707 P00966, 77 citrullinemia type I Urea cycle disorder Q5T6L4 PAH 5053 0171759 A0A024RBG4, 78 Phenylalanine Aminoacidopathy P00439 hydroxylase deficiency PAL 79 Phenylalanine Aminoacidopathy hydroxylase deficiency ATP8B1 5205 0081923 O43520 80 Progressive familial intrahepatic cholestasis Type 1 ABCB11 8647 0073734, O95342 81 Progressive 0276582 familial intrahepatic cholestasis Type 2; Progressive Familial Intrahepatic Cholestasis Type 3 ABCB4 5244 0005471 P21439 82 Progressive familial intrahepatic cholestasis Type 3; Progressive Familial Intrahepatic Cholestasis Type 2 TJP2 9414 0119139 B7Z2R3, 83 Progressive Q9UDY2, familial B7Z954 intrahepatic cholestasis Type 4 IVD 3712 0128928 P26440, 84 isovaleric Organic acidemia A0A0A0MT83 acidemia (IVD) GCDH 2639 0105607 A0A024R7F9, 85 glutaric acidemia Organic acidemia Q92947 type I ETFA 2108 0140374 A0A0S2Z3L0, 86 multiple acyl-CoA Organic acidemia P13804 dehydrogenase deficiency (a.k.a. glutaric aciduria type II) ETFB 2109 0105379 P38117 87 multiple acyl-CoA Organic acidemia dehydrogenase deficiency (a.k.a. glutaric aciduria type II) ETFDH 2110 0171503 B4DEQ0, 88 multiple acyl-CoA Organic acidemia Q16134 dehydrogenase deficiency (a.k.a. glutaric aciduria type II) ASL 435 0126522 A0A024RDL8, 89 argininosuccinate Urea cycle disorder P04424, lyase (ASL) A0A0S2Z316 deficiency D2HGDH 728294 0180902 B3KSR6, 90 D-2- Organic acidemia B4E3K7, hydroxyglutaric B5MCV2, aciduria type I Q8N465 HMGCL 3155 0117305 P35914 91 3-hydroxy-3- Organic academia methylglutaryl- Urea cycle disorder CoA lyase (3HMG) deficiency MCCC1 56922 0078070 Q68D27, 92 3-methylcrotonyl- Organic acidemia Q96RQ3, CoA carboxylase A0A0S2Z693, (3MCC) E9PHF7 deficiency MCCC2 64087 0131844, A0A140VK29, 93 3-methylcrotonyl- Organic acidemia 0281742, Q9HCC0 CoA carboxylase 0275300 (3MCC) deficiency ABCD4 5826 0119688 A0A024R6B9, 94 methylmalonic Organic acidemia O14678, acidemia with A0A024R6C8 homocystinuria HCFC1 3054 0172534 P51610, 95 methylmalonic Organic acidemia A6NEM2 acidemia with homocystinuria LMBRD1 55788 0168216 Q9NUN5 96 methylmalonic Organic acidemia acidemia with homocystinuria ARG1 383 0118520 P05089 97 arginase (ARG1) Urea cycle disorder deficiency SLC25A15 10166 0102743 Q9Y619 98 hyperammonemia- Urea cycle disorder hyperornithinemia- homocitrullinuria (HHH) syndrome SLC25A13 10165 0004864 Q9UJS0 99 citrin deficiency Urea cycle disorder citrullinemia type II ALAD 210 0148218 P13716 100 Acute Hepatic Porphyria porphyria CPOX 1371 0080819 P36551 101 Acute Hepatic Porphyria porphyria HMBS 3145 0256269, P08397 102 Acute Hepatic Porphyria 0281702 porphyria; Acute Intermittent Porphyria PPOX 5498 0143224 P50336, 103 Acute Hepatic Porphyria B4DY76 porphyria BTD 686 0169814 P43251 104 Biotinidase Organic acidemia Deficiency HLCS 3141 0159267 P50747 105 Holocarboxylase Organic acidemia Synthetase Deficiency PC 5091 0173599 P11498 106 Pyruvate Urea cycle disorder A0A024R5C5 Carboxylase Deficiency SLC7A7 9056 0155465 Q9UM01 107 Lysinuric Protein Urea cycle disorder A0A0S2Z502 Intolerance CPT2 1376 0157184 P23786 108 Carnitine Fatty Acid Oxidation A0A140VK13 Palmitoyltransferase A0A1B0GTB8 Type II (CPT II) Deficiency ACADM 34 0117054 P11310 109 Medium Chain Fatty Acid Oxidation A0A0S2Z366, Acyl-CoA B7Z911, Dehydrogenase Q5HYG7, (MCAD) Q5T4U5, Deficiency B4DJE7 ACADS 35 0122971 P16219 110 Short Chain Acyl- Fatty acid oxidation E5KSD5, CoA (SCAD) B4DUH1, Dehydrogenase E9PE82 Deficiency ACADVL 37 0072778 P49748 111 Very Long Chain Fatty acid oxidation B3KPA6 Acyl-CoA Dehydrogenase (VLCAD) Deficiency AGL 178 0162688 P35573 112 GSD III (Cori/ Liver glycogen storage A0A0S2A4E4 Forbe Disease or disorder Debrancher) G6PC 2538 0131482 P35575 113 GSDIa (Von Liver glycogen storage Gierke Disease) disorder GBE1 2632 0114480 Q04446 114 GSD IV (Andersen Liver glycogen storage Q59ET0 Disease, Brancher disorder Enzyme) PHKA1 5255 0067177 P46020 115 GSD IXa PHKA2 0044446   5256 P46019 116 GSD IXa Liver glycogen storage 5256 0044446 disorder PHKB 5257 0102893 Q93100 117 GSD IXb Liver glycogen storage disorder PHKG2 5261 0156873 P15735 118 GSD IXc Liver glycogen storage disorder SLC37A4 2542 0281500 O43826 119 GSDIb. c, d Liver glycogen storage 0137700 A0A024R3H9, disorder A8K0S7, A0A024R3L1, B4DUH2 PMM2 5373 0140650 O15305, 120 PMM2-CDG Glycosylation disorder A0A0S2Z4J6, Q59F02 CBS 102724560, 0160200 P35520, 121 Cystathionine Aminoacidopathy 875 P0DN79, Beta-Synthase Q9NTF0, Deficiency B7Z2D6 (Classic Homocystinuria); Homocystinuria FAH 2184 0103876 P16930 122 Tyrosinemia Type Aminoacidopathy I TAT 6898 0198650 P17735, 123 Tyrosinemia Type Aminoacidopathy A0A140VKB7 II Tyrosinemia Type III GALT 2592 0213930 P07902, 124 Galactosemia Carbohydrate disorder A0A0S2Z3Y7, due to galactose-1- B2RAT6 phosphate uridylyltranserase (GALT) deficiency GALK1 2584 0108479 P51570 125 Galactosemia Carbohydrate disorder GALE 2582 0117308 Q14376 126 Galactosemia Carbohydrate disorder G6PD 2539 0160211 P11413 127 Glucose-6- Carbohydrate disorder Phosphate Dehydrogenase (G6PD) Deficiency SLC3A1 6519 0138079 Q07837, 128 Cystinuria Aminoacidopathy A0A0S2Z4E1, B8ZZK1 SLC7A9 11136 0021488 P82251 129 Cystinuria Aminoacidopathy MTHFR 4524 0177000 P42898, 130 Homocystinuria Aminoacidopathy Q59GJ6, Q81U67 MTR 4548 0116984 Q99707 131 Homocystinuria Aminoacidopathy MTRR 4552 0124275 Q9UBK8 132 Homocystinuria Aminoacidopathy ATP7B 540 0123191 P35670, 133 Wilson Disease Metal transport disorder A0A024RDX3, Copper B7ZLR4, Metabolism B7ZLR3, Disorder E7ET55 HPRT1 3251 0165704 P00492, 134 Lesch-Nyhan Purine Metabolism A0A140VJL3 Syndrome Disorder Purine Metabolism Disorder HJV 148738 0168509 Q6ZVN8 135 Hemochromatosis, Type 2A HAMP 57817 0105697 P81172 136 Hemochromatosis Type 2B: Primary Hemochromatosis JAG1 182 0101384 P78504, 137 Alagille Syndrome Q99740 1 TTR 7276 0118271 P02766, 138 Familial TTR E9KL36 Amyloidoisis; Familial amyloid polyneuropathy AGXT 189 0172482 P21549 139 Primary Hyperoxaluria Type I LIPA 3988 0107798 P38571 140 Lysosomal Acid Lyososomal storage A0A0A0MT32 Lipase Deficiency disorder SERPING1 710 0149131 P05155, 141 Hereditary A0A0S2Z4J1, Angioedma B2R659, E7EWE5, B3KSP2, G5E9S2 HSD17B4 3295 0133835 P51659 142 D-Bifunctional Peroxisomal disorders Protein Deficiency X-linked Adrenoleukodystrophy UROD 7389 0126088 P06132 143 Porphyria Cutanea Tarda HFE 3077 0010704 Q30201 144 Porphyria Cutanea Tarda LPL 4023 0175445 P06858, 145 Lipoprotein Lipase A0A1B1RVA9 Deficiency (“hyperlipoproteinemia type Ia; Buerger-Gruetz syndrome, or Familial hyperchylomicronemia) GRHPR 9380 0137106 Q9UBQ7 146 Primary Hyperoxaluria Type II HOGA1 112817 0241935 Q86XE5 147 Primary Hyperoxaluria Type III LDLR 3949 0130164 P01130, 148 Homozygous A0A024R7D5 Familial Hypercholesterolemia ACAD8 27034 0151498 Q9UKU7 149 isobutyryl-CoA Organic acidemia dehydrogenase (IBD) deficiency ACADSB 36 0196177 P45954, 150 short-branched Organic acidemia A0A0S2Z3P9 chain acyl-CoA dehydrogenase (SBCAD) deficiency ACAT1 38 0075239 A0A140VJX1, 151 beta-ketothiolase Organic acidemia P24752 deficiency ACSF3 197322 0176715 Q4G176, 152 combined malonic Organic acidemia F5H5A1 and methylmalonic aciduria ASPA 443 0108381 P45381, 153 Canavan disease Organic acidemia Q6FH48 AUH 549 0148090 Q13825, 154 3- Organic acidemia B4DYI6 methylglutaconic acidemia type I DNAJC19 131118 0205981 Q96DA6, 155 dilated Organic acidemia A0A0S2Z5X1 cardiomyopathy with ataxia syndrome (causes 3- methylglutaconic aciduria) ETHE1 23474 0105755 A0A0S2Z580, 156 ethylmalonic Organic acidemia O95571, encephalopathy A0A0S2Z5N8, A0A0S2Z5B3, B2RCZ7 FBP1 2203 0165140 P09467, 157 fructose 1,6- Organic acidemia Q2TU34 Bisphosphatase deficiency FTCD 10841 0160282, O95954 158 glutamate Organic acidemia 0281775 formiminotransferase deficiency (FIGLU GSS 2937 0100983 P48637, 159 glutathione Organic acidemia V9HWJ1 synthetase deficiency HIBCH 26275 0198130 A0A140VJL0, 160 3- Organic acidemia Q6NVY1 hyroxyisobutyryl- CoA hydrolase deficiency IDH2 3418 0182054 P48735, 161 D-2- Organic acidemia B4DSZ6 hydroxyglutaric aciduria type II L2HGDH 79944 0087299 Q9H9P8 162 L-2- Organic acidemia hydroxyglutaric aciduria MLYCD 23417 0103150 O95822 163 malonic acidemia Organic acidemia OPA3 80207 0125741 Q9H6K4, 164 Costeff syndrome/ Organic acidemia B4DK77 3- methylglutaconic aciduria type III OPLAH 26873 0178814 O14841 165 5-oxoprolinase Organic acidemia deficiency OXCT1 5019 0083720 A0A024R040, 166 SCOT deficiency Organic acidemia P55809 POLG 5428 0140521 E5KNU5, 167 3- Organic acidemia P54098 methylglutaconic aciduria PPM1K 152926 0163644 Q8N3J5 168 maple syrup urine Organic acidemia disease (MSUD), variant type SERAC1 84947 0122335 Q96JX3 169 Megdel Syndrome Organic acidemia SLC25A1 6576 0100075 D9HTE9, 170 D,L-2- Organic acidemia B4DP62, hydroxyglutaric P53007 aciduria SUCLA2 8803 0136143 E5KS60, 171 succinate-CoA Organic acidemia Q9P2R7, ligase deficiency, Q9Y4T0 methylmalonic aciduria SUCLG1 8802 0163541 P53597 172 succinate-CoA Organic acidemia ligase deficiency, methylmalonic aciduria TAZ 6901 0102125 A0A0S2Z4K0, 173 Barth syndrome Organic acidemia Q16635, A6XNE1, A0A0S2Z4E6, A0A0S2Z4K9, A0A0S2Z4F4 AGK 55750 0006530, A4D1U5, 174 3- Organic acidemia 0262327 Q53H12 methylglutaconic aciduria CLPB 81570 0162129 Q9H078, 175 3- Organic acidemia A0A140VK11 methylglutaconic aciduria TMEM70 54968 0175606 Q9BUB7 176 3- Organic acidemia methylglutaconic aciduria ALDH18A1 5832 0059573 P54886 177 ALDH18A1- Urea cycle disorder related cutis laxa OAT 4942 0065154 A0A140VJQ4, 178 gyrate atrophy Urea cycle disorder P04181 (OAT) CA5A 763 0174990 P35218 179 carbonic Urea cycle disorder anhydrase deficiency GLUD1 2746 0148672 P00367, 180 glutamate Urea cycle disorder E9KL48 dehydrogenase deficiency GLUL 2752 0135821 A8YXX4, 181 glutamine Urea cycle disorder P15104 synthetase deficienc UMPS 7372 0114491 A8K5J1, 182 Orotic Aciduria Urea cycle disorder P11172 SLC22A5 6584 0197375 O76082 183 carnitine- Fatty acid oxidation acylcarnitine translocase (CACT) deficiency CPT1A 1374 0110090 P50416, 184 carnitine Fatty acid oxidation A0A024R5F4, palmitoyltransferase B2RAQ8, type I (CPT I) Q8WZ48 deficiency HADHA 3030 0084754 E9KL44, 185 long chain 3- Fatty acid oxidation P40939 hydroxyacyl-CoA dehydrogenase (LCHAD) deficiency HADH 3033 0138796 Q16836, 186 medium/short Fatty acid oxidation B3KTT6 chain acyl-CoA dehydrogenase (M/SCHAD) deficiency SLC52A1 55065 0132517 Q9NWF4 187 Riboflavin Fatty acid oxidation transporter deficiency SLC52A2 79581 0185803 Q9HAB3 188 Riboflavin Fatty acid oxidation transporter deficiency SLC52A3 113278 0101276 K0A6P4, 189 Riboflavin Fatty acid oxidation Q9NQ40 transporter deficiency HADHB 3032 0138029 P55084, 190 Trifunctional Fatty acid oxidation F5GZQ3 protein deficiency GYS2 2998 0111713 P54840 191 GSD 0 (Glycogen Liver glycogen storage synthase, liver disorder isoform) PYGL 5836 0100504 P06737 192 GSD VI (Hers Liver glycogen storage disease) disorder SLC2A2 6514 0163581 P11168, 193 Fanconi-Bickel Liver glycogen storage Q6PAU8 syndrome disorder ALG1 56052 0033011 Q9BT22 194 ALG1-CDG Glycosylation disorder ALG2 85365 0119523 A0A024R184, 195 ALG2-associated Glycosylation disorder Q9H553 myasthenic syndrome ALG3 10195 0214160 Q92685, 196 ALG3-CDG Glycosylation disorder C9J7S5 ALG6 29929 0088035 Q9Y672 197 ALG6-CDG Glycosylation disorder ALG8 79053 0159063 Q9BVK2, 198 ALG8-CDG Glycosylation disorder A0A024R5K5 ALG9 79796 0086848 Q9H6U8 199 ALG9-CDG Glycosylation disorder ALG11 440138 0253710 Q2TAA5 200 ALG11-CDG Glycosylation disorder ALG12 79087 0182858 A0A024R4V6, 201 ALG12-CDG Glycosylation disorder Q9BV10 ALG13 79868 0101901 Q9NP73, 202 ALG13-CDG Glycosylation disorder A0A087WX43, A0A087WT15 ATP6V0A2 23545 0185344 Q9Y487 203 ATP6V0A2- Glycosylation disorder associated cutis laxa B3GLCT 145173 0187676 Q6Y288 204 B3GLCT-CDG Glycosylation disorder CHST14 113189 0169105 Q8NCH0 205 CHST14-CDG Glycosylation disorder COG1 9382 0166685 Q8WTW3 206 COG1-CDG Glycosylation disorder COG2 22796 0135775 Q14746, 207 COG2-CDG Glycosylation disorder B1ALW7 COG4 25839 0103051 A0A0A0MS45, 208 COG4-CDG Glycosylation disorder Q8N8L9, Q9H9E3, J3KNI1 COG5 10466 0164597, Q9UP83 209 COG5-CDG Glycosylation disorder 0284369 COG6 57511 0133103 A0A140VJG7, 210 COG6-CDG Glycosylation disorder Q9Y2V7, A0A024RDW5 COG7 91949 0168434 A0A0S2Z652, 211 COG7-CDG Glycosylation disorder P83436 COG8 84342 0272617 A0A024R6Z6, 212 COG8-CDG Glycosylation disorder Q96MW5 DOLK 22845 0175283 A0A0S2Z597, 213 DOLK-CDG Glycosylation disorder Q9UPQ8 DHDDS 79947 0117682 Q86SQ9 214 DHDDS-CDG Glycosylation disorder DPAGT1 1798 0172269 A0A024R3H8, 215 DPAGT1-CDG Glycosylation disorder Q9H3H5 DPM1 8813 0000419 O60762, 216 DPM1-CDG Glycosylation disorder Q5QPK2, A0A0S2Z4Y5 DPM2 8818 0136908 O94777 217 DPM2-CDG Glycosylation disorder DPM3 54344 0179085 A0A140VJI4, 218 DPM3-CDG Glycosylation disorder Q9P2X0, Q86TM7 G6PC3 92579 0141349 Q9BUM1 219 Congenital Glycosylation disorder neutropenia GFPT1 2673 0198380 Q06210 220 Congenital Glycosylation disorder myasthenic syndrome GMPPA 29926 0144591 A0A024R482, 221 GMPPA-CDG Glycosylation disorder Q96IJ6 GMPPB 29925 0173540 Q9Y5P6 222 Congenital Glycosylation disorder muscular dystrophy, congenital myasthenic syndrome, and dystroglycanopathy MAGT1 84061 0102158 A0A087WU53, 223 MAGT1-CDG; X- Glycosylation disorder Q9H0U3 linked immunodeficiency with magnesium defect, Epstein- Barr virus infection and neoplasia (XMEN) syndrome MAN1B1 11253 0177239 Q9UKM7 224 MAN1B1-CDG Glycosylation disorder MGAT2 4247 0168282 Q10469 225 MGAT2-CDG Glycosylation disorder MOGS 7841 0115275 Q13724, 226 MOGS-CDG Glycosylation disorder Q58F09 MPDU1 9526 0129255 J3QW43, 227 MPDU1-CDG Glycosylation disorder O75352, A0A0S2Z4W8, B4DLH7 MPI 4351 0178802 H3BPP3, 228 MPI-CDG Glycosylation disorder Q8NHZ6, B4DW50, F5GX71, P34949, H3BPB8 NGLY1 55768 0151092 Q96IV0 229 NGLY1-CDG Glycosylation disorder PGM1 5236 0079739 B7Z6C2, 230 PGM1-CDG Glycosylation disorder P36871, B4DDQ8 PGM3 5238 0013375 O95394, 231 PGM3-CDG Glycosylation disorder A0A087WT27 RFT1 91869 0163933 Q96AA3 232 RFT1-CDG Glycosylation disorder SEC23B 10483 0101310 Q15437, 233 SEC23B-CDG Glycosylation disorder B4DJW8 SLC35A1 10559 0164414 P78382 234 SLC35A1-CDG Glycosylation disorder SLC35A2 7355 0102100 P78381, 235 SLC35A2-CDG Glycosylation disorder A6NFI1, A6NKM8, B4DE15 SLC35C1 55343 0181830 Q96A29, 236 SLC35C1-CDG Glycosylation disorder B3KQH0 SSR4 6748 0180879 P51571 237 SSR4-CDG Glycosylation disorder SRD5A3 79644 0128039 Q9H8P0 238 SRD5A3-CDG Glycosylation disorder TMEM165 55858 0134851 Q9HC07 239 TMEM165-CDG Glycosylation disorder TRIP11 9321 0100815 Q15643 240 TRIP11-CDG Glycosylation disorder TUSC3 7991 0104723 Q13454 241 TUSC3-CDG Glycosylation disorder ALG14 199857 0172339 Q96F25 242 ALG14-CDG Glycosylation disorder B4GALT1 2683 0086062 P15291, 243 B4GALT1-CDG Glycosylation disorder W6MEN3 DDOST 1650 0244038 A0A024RAD5, 244 DDOST-CDG Glycosylation disorder P39656 NUS1 116150 0153989 Q96E22 245 NUS1-CDG Glycosylation disorder RPN2 6185 0118705 P04844 246 RPN2-CDG Glycosylation disorder SEC23A 10484 0100934 Q15436 247 SEC23A-CDG Glycosylation disorder SLC35A3 23443 0117620 Q9Y2D2, 248 SLC35A3-CDG Glycosylation disorder A0A1W2PRT7, A0A1W2PSD1, A0A1W2PQL8 ST3GAL3 6487 0126091 Q11203 249 ST3GAL3-CDG Glycosylation disorder STT3A 3703 0134910 P46977 250 STT3A-CDG Glycosylation disorder STT3B 201595 0163527 Q8TCJ2 251 STT3B-CDG Glycosylation disorder AGA 175 0038002 P20933 252 Aspartylglucosaminuria Lyososomal storage disorder ARSA 410 0100299 A0A0C4DFZ2, 253 Metachromatic Lyososomal storage B4DVI5, leukodystrophy disorder P15289 ARSB 411 0113273 A0A024RAJ9, 254 Mucopolysaccharidosis Lyososomal storage P15848, type VI disorder A8K4A0 ASAH1 427 0104763 A8K0B6, 255 Farber disease Lyososomal storage Q13510, disorder Q53H01 ATP13A2 23400 0159363 Q8N4D4, 256 Neuronal ceroid Lyososomal storage Q9NQ11, lipofuscinosis 12 disorder Q8NBS1 (CLN12), Kufor- Rakeb syndrome (KRS) CLN3 1201 0188603, A0A024QZB8, 257 Neuronal ceroid Lyososomal storage 0261832 Q13286, lipofuscinosis 3 disorder B4DMY6, (CLN3) Q2TA70, B4DFF3 CLN5 1203 0102805 A0A024R644, 258 Neuronal ceroid Lyososomal storage O75503 lipofuscinosis 5 disorder (CLN5) CLN6 54982 0128973 A0A024R601, 259 Neuronal ceroid Lyososomal storage Q9NWW5 lipofuscinosis 6 disorder (CLN6) CLN8 2055 0182372, A0A024QZ57, 260 Neuronal ceroid Lyososomal storage 0278220 Q9UBY8 lipofuscinosis 8 disorder (CLN8) CTNS 1497 0040531 A0A0S2Z3I9, 261 cystinosis Lyososomal storage O60931, disorder A0A0S2Z3K3 CTSA 5476 0064601 P10619, 262 Galactosialidosis Lyososomal storage X6R8A1, disorder B4E324, X6R5C5 CTSD 1509 0117984 P07339, 263 Neuronal ceroid Lyososomal storage V9HWI3 lipofuscinosis 10 disorder (CLN10) CTSF 8722 0174080 Q9UBX1 264 Neuronal ceroid Lyososomal storage lipofuscinosis 13 disorder (CLN13) CTSK 1513 0143387 P43235 265 Pycnodysostosis Lyososomal storage disorder DNAJC5 80331 0101152 Q6AHX3, 266 Neuronal ceroid Lyososomal storage Q9H3Z4 lipofuscinosis 4 disorder (CLN4) FUCA1 2517 0179163 P04066, 267 Fucosidosis Lyososomal storage B5MDC5 disorder GAA 2548 0171298 P10253 268 Pompe disease Lyososomal storage disorder GALC 2581 0054983 A0A0A0MQV0, 269 Krabbe disease Lyososomal storage P54803 disorder GALNS 2588 0141012 P34059, 270 Mucopolysaccharidosis Lyososomal storage Q96I49, type IVa disorder Q6YL38 GLA 2717 0102393 P06280, 271 Fabry disease Lyososomal storage Q53Y83 disorder GLB1 2720 0170266 P16278, 272 GM1 Lyososomal storage B7Z6Q5 gangliosidosis, disorder Mucopolysaccharidosis IVb GM2A 2760 0196743 P17900 273 GM2- Lyososomal storage gangliosidosis, AB disorder variant GNPTAB 79158 0111670 Q3T906 274 Mucolipidosis type Lyososomal storage II alpha/beta, disorder Mucolipidosis III alpha/beta GNPTG 84572 0090581 Q9UJJ9 275 Mucolipidosis III Lyososomal storage gamma disorder GNS 2799 0135677 A0A024RBC5, 276 Mucopolysaccharidosis Lyososomal storage P15586, type IIID disorder Q7Z3X3 GRN 2896 0030582 P28799 277 Neuronal ceroid Lyososomal storage lipofuscinosis 11 disorder (CLN11), frontotemporal dementia GUSB 2990 0169919 P08236 278 Mucopolysaccharidosis Lyososomal storage type VII disorder HEXA 3073 0213614 A0A0S2Z3W3, 279 Tay-Sachs disease Lyososomal storage P06865, disorder B4DVA7, H3BP20 HEXB 3074 0049860 A0A024RAJ6, 280 Sandhoff diseaase Lyososomal storage P07686, disorder Q5URX0 HGSNAT 138050 0165102 Q68CP4, 281 Mucopolysaccharidosis Lyososomal storage Q8IVU6 type IIIC disorder HYAL1 3373 0114378 A0A024R2X3, 282 Mucopolysaccharidosis Lyososomal storage QI2794, type IX disorder B3KUI5, A0A0S2Z3Q0 IDS 3423 0010404 P22304, 283 Mucopolysaccharidosis Lyososomal storage B4DGD7 type II disorder IDUA 3425 0127415 P35475 284 Mucopolysaccharidosis Lyososomal storage type I disorder KCTD7 154881 0243335 Q96MP8, 285 Neuronal ceroid Lyososomal storage A0A024RDN7 lipofuscinosis 14 disorder (CLN14) LAMP2 3920 0005893 P13473 286 Danon disease Lyososomal storage disorder MAN2B1 4125 0104774 O00754, 287 alpha- Lyososomal storage A8K6A7 mannosidosis disorder MANBA 4126 0109323 O00462 288 beta-mannosidosis Lyososomal storage disorder MCOLN1 57192 0090674 Q9GZU1 289 Mucolipidosis type Lyososomal storage IV disorder MFSD8 256471 0164073 Q8NHS3 290 Neuronal ceroid Lyososomal storage lipofuscinosis 7 disorder (CLN7) NAGA 4668 0198951 A0A024R1Q5, 291 Schindler disease Lyososomal storage P17050 disorder NAGLU 4669 0108784 A0A140VJE4, 292 Mucopolysaccharidosis Lyososomal storage P54802 IIIB disorder NEU1 4758 0204386, Q5JQI0, 293 Mucolipidosis type Lyososomal storage 0227315, Q99519 I, Sialidosis I disorder 0227129, 0223957, 0234846, 0184494, 0228691, 0234343 NPC1 4864 0141458 O15118 294 Niemann-Pick Lyososomal storage type C disorder NPC2 10577 0119655 A0A024R6C0, 295 Niemann-Pick Lyososomal storage P61916, type C disorder G3V3E8 SGSH 6448 0181523 P51688 296 Mucopolysaccharidosis Lyososomal storage IIIA disorder PPT1 5538 0131238 P50897 297 Neuronal ceroid Lyososomal storage lipofuscinosis 1 disorder (CLN1) PSAP 5660 0197746 P07602, 298 Prosaposin Lyososomal storage A0A024QZQ2 deficiency, SapA disorder deficiency (Krabbe variant), SapB deficiency (MLD variant), SapC deficiency (Gaucher variant) SLC17A5 26503 0119899 Q9NRA2 299 Infantile sialic acid Lyososomal storage storage disease, disorder Salla disease SMPD1 6609 0166311 P17405, 300 Niemann Pick Lyososomal storage Q59EN6, types A and B disorder E9LUE8, Q8IUN0, E9LUE9 SUMF1 285362 0144455 Q8NBK3 301 Multiple sulfatase Lyososomal storage deficiency disorder TPP1 1200 0166340 O14773 302 Neuronal ceroid Lyososomal storage lipofuscinosis 2 disorder (CLN2) AHCY 191 0101444 P23526, 303 Hypermethioninemia Aminoacidophaty Q1RMG2 GNMT 27232 0124713 A0A0S2Z5F2, 304 Hypermethioninemia Aminoacidophaty Q14749, V9HW60 MAT1A 4143 0151224 Q00266 305 Hypermethioninemia Aminoacidophaty GCH1 2643 0131979 A0A024R642, 306 BH4 cofactor Aminoacidophaty P30793, deficiency Q8IZH9 PCBD1 5092 0166228 P61457 307 BH4 cofactor Aminoacidophaty deficiency PTS 5805 0150787 Q03393 308 BH4 cofactor Aminoacidophaty deficiency QDPR 5860 0151552 A0A140VKA9, 309 BH4 cofactor Aminoacidophaty P09417 deficiency SPR 6697 0116096 P35270 310 BH4 cofactor Aminoacidophaty deficiency DNAJC12 56521 0108176 Q6IAH1, 311 Phenylalanine, Aminoacidophaty Q9UKB3 tyrosine, and tryptophan hydroxylases heat shock co-chaperone deficiency ALDH4A1 8659 0159423 P30038, 312 Hyperprolinemia Aminoacidophaty A0A024RAD8 PRODH 5625 0100033 O43272 313 Hyperprolinemia Aminoacidophaty HPD 3242 0158104 P32754 314 Tyrosinemia type Aminoacidophaty II GBA 2629 0177628, A0A068F658, 315 Gaucher disease 0262446 P04062, B7Z6S9 HGD 3081 0113924 Q93099, 316 Alkaptonuria B3KW64 AMN 81693 0166126 Q9BXJ7, 317 Combined Organic acidemia B3KP64 Methylmalonic Acidemia and Homocystinuria CD320 51293 0167775 Q9NPF0 318 Combined Organic acidemia Methylmalonic Acidemia and Homocystinuria CUBN 8029 0107611 O60494 319 Combined Organic acidemia Methylmalonic Acidemia and Homocystinuria GIF 2694 0134812 P27352 320 Combined Organic acidemia Methylmalonic Acidemia and Homocystinuria TCN1 6947 0134827 P20061 321 Combined Organic acidemia Methylmalonic Acidemia and Homocystinuria TCN2 6948 0185339 P20062 322 Combined Organic acidemia Methylmalonic Acidemia and Homocystinuria PREPL 9581 0138078 Q4J6C6 323 Cystinuria Aminoacidophaty PHGDH 26227 0092621 O43175 324 Disorders of Aminoacidophaty Serine Biosynthesis PSAT1 29968 0135069 A0A024R280, 325 Disorders of Aminoacidophaty Q9Y617, Serine A0A024R222 Biosynthesis PSPH 5723 0146733 A0A024RDL3, 326 Disorders of Aminoacidophaty P78330 Serine Biosynthesis AMT 275 0145020 A0A024R2U7, 327 Glycine Aminoacidophaty P48728 Encephalopathy GCSH 2653 0140905 P23434 328 Glycine Aminoacidophaty Encephalopathy GLDC 2731 0178445 P23378 329 Glycine Aminoacidophaty Encephalopathy LIAS 11019 0121897 O43766, 330 Glycine Aminoacidophaty Q6P5Q6, Encephalopathy B4E0L7, A0A024R9W0, A0A1W2PQE9, A0A1X7SBR7 NFU1 27247 0169599 Q9UMS0 331 Glycine Aminoacidophaty Encephalopathy SLC6A9 6536 0196517 P48067, 332 Glycine Aminoacidophaty B7Z3W8, Encephalopathy B7Z589 SLC2A1 6513 0117394 P11166, 333 Glucose Carbohydrate disorder Q59GX2 Transporter Type 1 Deficiency ATP7A 538 0165240 B4DRW0, 334 ATP7A-Related Metal transport disorder Q04656, Disorders Q762B6 Copper Metabolism Disorder AP1S1 1174 0106367 A0A024QYT6, 335 Copper Metal transport disorder P61966 Metabolism Disorder CP 1356 0047457 A5PL27, 336 Copper Metal transport disorder P00450 Metabolism Disorder SLC33A1 9197 0169359 O00400 337 Copper Metal transport disorder Metabolism Disorder PEX7 5191 0112357 O00628, 338 Adult Refsum Peroxisomal disorders Q6FGN1 Disease Rhizomelic Chondrodysplasia Punctata Spectrum PHYH 5264 0107537 O14832 339 Adult Refsum Peroxisomal disorders Disease AGPS 8540 0018510 O00116, 340 Rhizomelic Peroxisomal disorders B7Z3Q4 Chondrodysplasia Punctata Spectrum GNPAT 8443 0116906 O15228 341 Rhizomelic Peroxisomal disorders Chondrodysplasia Punctata Spectrum ABCD1 215 0101986 P33897 342 X-linked Peroxisomal disorders Adrenoleukodystrophy ACOX1 51 0161533 Q15067 343 X-linked Peroxisomal disorders Adrenoleukodystrophy PEX1 5189 0127980 O43933, 344 X-linked Peroxisomal disorders A0A0C4DG33, Adrenoleukodystrophy B4DER6 PEX2 5828 0164751 P28328 345 X-linked Peroxisomal disorders Adrenoleukodystrophy PEX3 8504 0034693 P56589 346 X-linked Peroxisomal disorders Adrenoleukodystrophy PEX5 5830 0139197 A0A0S2Z480, 347 X-linked Peroxisomal disorders P50542, Adrenoleukodystrophy B4DR50, A0A0S2Z4F3, A0A0S2Z4H1, B4E0T2 PEX6 5190 0124587 A0A024RD09, 348 X-linked Peroxisomal disorders Q13608 Adrenoleukodystrophy PEX10 5192 0157911 A0A024R068, 349 X-linked Peroxisomal disorders O60683, Adrenoleukodystrophy A0A024R0A4 PEX12 5193 0108733 O00623 350 X-linked Peroxisomal disorders Adrenoleukodystrophy PEX13 5194 0162928 Q92968 351 X-linked Peroxisomal disorders Adrenoleukodystrophy PEX14 5195 0142655 O75381 352 X-linked Peroxisomal disorders Adrenoleukodystrophy PEX16 9409 0121680 Q9Y5Y5 353 X-linked Peroxisomal disorders Adrenoleukodystrophy PEX19 5824 0162735 P40855, 354 X-linked Peroxisomal disorders A0A0S2Z497 Adrenoleukodystrophy PEX26 55670 0215193 A0A024R100, 355 X-linked Peroxisomal disorders Q7Z412, Adrenoleukodystrophy A0A0S2Z5M7, Q7Z2D7 AMACR 23600 0242110 Q9UHK6 356 Zellweger Peroxisomal disorders Spectrum Disorder ADA 100 0196839 A0A0S2Z381, 357 Purine Metabolism Purine Metabolism P00813, Disorder Disorder F5GWI4 ADSL 158 0239900 P30566, 358 Purine Metabolism Purine Metabolism X5D8S6, Disorder Disorder X5D7W4, A0A1B0GWJ0 AMPD1 270 0116748 P23109 359 Purine Metabolism Purine Metabolism Disorder Disorder GPHN 10243 0171723 Q9NQX3 360 Purine Metabolism Purine Metabolism Disorder Disorder MOCOS 55034 0075643 Q96EN8 361 Purine Metabolism Purine Metabolism Disorder Disorder MOCS1 4337 0124615 A0A024RD17, 362 Purine Metabolism Purine Metabolism Q9NZB8 Disorder Disorder PNP 4860 0198805 P00491, 363 Purine Metabolism Purine Metabolism V9HWH6 Disorder Disorder XDH 7498 0158125 P47989 364 Purine Metabolism Purine Metabolism Disorder Disorder SUOX 6821 0139531 A0A024RB79, 365 Purine Metabolism Purine Metabolism P51687 Disorder Disorder OGDH 4967 0105953 A0A140VJQ5, 366 2-Ketoglutarate PYRUVATE Q02218, Dehydrogenase METABOLISM AND B4E3E9, Deficiency TRICARBOXYLIC ACID E9PCR7, CYCLE DEFECT E9PDF2 SLC25A19 60386 0125454 Q5JPC1, 367 2-Ketoglutarate PYRUVATE Q9HC21 Dehydrogenase METABOLISM AND Deficiency TRICARBOXYLIC ACID CYCLE DEFECT DHTKD1 55526 0181192 Q96HY7 368 2-Ketoglutarate PYRUVATE Dehydrogenase METABOLISM AND Deficiency TRICARBOXYLIC ACID CYCLE DEFECT SLC13A5 284111 0141485 Q68D44, 369 Citrate Transporter PYRUVATE Q86YT5 Deficiency METABOLISM AND TRICARBOXYLIC ACID CYCLE DEFECT FH 2271 0091483 A0A0S2Z4C3, 370 Fumarase PYRUVATE P07954 Deficiency METABOLISM AND TRICARBOXYLIC ACID CYCLE DEFECT DLAT 1737 0150768 P10515, 371 Pyruvate PYRUVATE Q86YI5 Dehydrogenase METABOLISM AND Deficiency TRICARBOXYLIC ACID CYCLE DEFECT MPC1 51660 0060762 Q5TI65, 372 Pyruvate PYRUVATE Q9Y5U8 Dehydrogenase METABOLISM AND Deficiency TRICARBOXYLIC ACID CYCLE DEFECT PDHA1 5160 0131828 A0A024RBX9, 373 Pyruvate PYRUVATE P08559 Dehydrogenase METABOLISM AND Deficiency TRICARBOXYLIC ACID CYCLE DEFECT PDHB 5162 0168291 P11177 374 Pyruvate PYRUVATE Dehydrogenase METABOLISM AND Deficiency TRICARBOXYLIC ACID CYCLE DEFECT PDHX 8050 0110435 O00330 375 Pyruvate PYRUVATE Dehydrogenase METABOLISM AND Deficiency TRICARBOXYLIC ACID CYCLE DEFECT PDP1 54704 0164951 Q9P0J1, 376 Pyruvate PYRUVATE Q6P1N1, Dehydrogenase METABOLISM AND A0A024R9C0 Deficiency TRICARBOXYLIC ACID CYCLE DEFECT ABCC2 1244 0023839 Q92887 377 Dubin-Johnson syndrome SLCO1B1 10599 0134538 A0A024RAU7, 378 Rotor Syndrome Q05CV5, Q9Y6L6 SLCO1B3 28234 0111700 B3KP78, 379 Rotor Syndrome Q9NPD5 HFE2 148738 0168509 Q6ZVN8, 380 Hemochromatosis, A8K466, type 2A A0A024R4F5 ADAMTS13 11093 0160323, Q76LX8 381 Congenital 0281244 thrombotic thrombocytopenic purpura due to ADAMTS-13 deficiency PYGM 5837 0068976 P11217 382 McArdle's Disease COL1A2 1278 0164692 A0A0S2Z3H5, 383 Ehlers-Danlos P08123 syndrome, cardiac valvular type TNFRSF11B 4982 0164761 O00300 384 Juvenile Paget's disease TSC1 7248 0165699 Q86WV8, 385 Tuberous sclerosis Q92574, X5D9D2, Q32NF0 TSC2 7249 0103197 P49815, 386 Tuberous sclerosis X5D7Q2, B3KWH7, Q5HYF7, H3BMQ0, X5D2U8 DHCR7 1717 0172893 A0A024R5F7, 387 Smith-Lemli-Opitz Q9UBM7 Syndrome PGK1 5230 0102144 P00558, 388 D- V9HWF4 glycericacidemia VLDLR 7436 0147852 P98155, 389 Dysequilibrium Q5VVF5 syndrome KYNU 8942 0115919 Q16719 390 Encephalopathy due to hydroxykynureninuria F5 2153 0198734 P12259 391 Factor V deficiency C3 718 0125730 B4DR57, 392 Atypical hemolytic P01024, uremic syndrome V9HWA9 with C3 anomaly COL4A1 1282 0187498 A5PKV2, 393 Autosomal F5H5K0, dominant familial P02462 hematuria - retinal arteriolar tortuosity - contractures CFH 3075 0000971 A0A024R962, 394 Atypical hemolytic P08603, uremic syndrome A0A0D9SG88 SLC12A2 6558 0064651 P55011, 395 Bartter syndrome Q53ZR1, type I (neonatal) B7ZM24 GK 2710 0198814 B4DH54, 396 Glycerol kinase P32189 deficiency SFTPC 6440 0168484 A0A0A0MTC9, 397 Chronic P11686, respiratory distress A0A0S2Z4Q0, with surfactant E5RI64 metabolism deficiency CRTAP 10491 0170275 O75718 398 Osteogenesis Imperfecta VII P3H1 64175 0117385 Q32P28 399 Osteogenesis Imperfecta VIII COL7A1 1294 0114270 Q02388, 400 Autosomal Q59F16 recessive dystrophic epidermolysis bullosa PKLR 5313 0143627 P30613 401 Pyruvate Kinase deficiency TALDO1 6888 0177156 A0A140VK56, 402 Transaldolase P37837 deficiency TF 7018 0091513 A0PJA6, 403 Atransferrinemia P02787, (familial Q06AH7 hypotransferrinemia) EPCAM 4072 0119888 P16422 404 Intestinal epithelial dysplasia VHL 7428 0134086 A0A024R2F2, 405 Familial P40337, erythrocytosis type A0A0S2Z4K1 2; von Hippel Lindau disease GC 2638 0145321 P02774 406 Vitamin D deficiency SERPINA1 5265 0197249, E9KL23, 407 Alpha-1 0277377 P01009 antitrypsin deficiency ABCC6 368 0091262, O95255 408 Pseudoxanthoma 0275331 elasticum F8 2157 0185010 P00451 409 Hemophilia A F9 2158 0101981 P00740 410 Hemophilia B ApoB 338 0084674 P04114 411 Familial hypercholesterolemia PCSK9 255738 0169174 Q8NBP7 412 Familial hypercholesterolemia LDLRAP1 26119 0157978 B3KR97, 413 Familial Q5SW96 hypercholesterolemia ABCG5 64240 0138075 Q9H222 414 Sitosterolemia ABCG8 64241 0143921 Q9H221 415 Sitosterolemia LCAT 3931 0213398 A0A140VK24, 416 Lecithin P04180 cholesterol acyltransferase deficiency SPINK5 11005 0133710 Q9NQ38 417 Netherton syndrome GNE 10020 0159921 Q9Y223 418 Inclusion body myopathy 2

In some embodiments, the targeted lipid particle or lentiviral vector contains an exogenous agent that is capable of targeting a T cell. In some embodiments, the exogenous agent capable of targeting a T cell is a chimeric antigen receptor (CAR), a T cell receptor, an integrin, an ion channel, a pore forming protein, a Toll-Like Receptor, an interleukin receptor, a cell adhesion protein, or a transport protein.

In some embodiments, the CAR is or comprises a first generation CAR comprising an antigen binding domain, a transmembrane domain, and signaling domain (e.g., one, two or three signaling domains). In some embodiments, the CAR comprises a third generation CAR comprising an antigen binding domain, a transmembrane domain, and at least three signaling domains. In some embodiments, a fourth generation CAR comprising an antigen binding domain, a transmembrane domain, three or four signaling domains, and a domain which upon successful signaling of the CAR induces expression of a cytokine gene. In some embodiments, the antigen binding domain is or comprises an scFv or Fab.

In some embodiments, a CAR antigen binding domain is or comprises an antibody or antigen-binding portion thereof. In some embodiments, a CAR antigen binding domain is or comprises an scFv or Fab. In some embodiments a CAR antigen binding domain comprises an scFv or Fab fragment of a T-cell alpha chain antibody; T-cell β chain antibody; T-cell γ chain antibody; T-cell δ chain antibody; CCR7 antibody; CD3 antibody; CD4 antibody; CD5 antibody; CD7 antibody; CD8 antibody; CD11b antibody; CD11c antibody; CD16 antibody; CD19 antibody; CD20 antibody; CD21 antibody; CD22 antibody; CD25 antibody; CD28 antibody; CD34 antibody; CD35 antibody; CD40 antibody; CD45RA antibody; CD45RO antibody; CD52 antibody; CD56 antibody; CD62L antibody; CD68 antibody; CD80 antibody; CD95 antibody; CD117 antibody; CD127 antibody; CD133 antibody; CD137 (4-1 BB) antibody; CD163 antibody; F4/80 antibody; IL-4Ra antibody; Sca-1 antibody; CTLA-4 antibody; GITR antibody GARP antibody; LAP antibody; granzyme B antibody; LFA-1 antibody; MR1 antibody; uPAR antibody; or transferrin receptor antibody.

In some embodiments, a CAR binding domain binds to a cell surface antigen of a cell. In some embodiments, a cell surface antigen is characteristic of one type of cell. In some embodiments, a cell surface antigen is characteristic of more than one type of cell.

In some embodiments, the antigen binding domain of the CAR targets an antigen characteristic of a T cell. In some embodiments, the antigen characteristic of a T cell is selected from a cell surface receptor, a membrane transport protein (e.g., an active or passive transport protein such as, for example, an ion channel protein, a pore-forming protein, etc.), a transmembrane receptor, a membrane enzyme, and/or a cell adhesion protein characteristic of a T cell. In some embodiments, an antigen characteristic of a T cell may be a G protein-coupled receptor, receptor tyrosine kinase, tyrosine kinase associated receptor, receptor-like tyrosine phosphatase, receptor serine/threonine kinase, receptor guanylyl cyclase, histidine kinase associated receptor, AKT1; AKT2; AKT3; ATF2; BCL10; CALM1; CD3D (CD3δ); CD3E (CD3ε); CD3G (CD3γ); CD4; CD8; CD28; CD45; CD80 (B7-1); CD86 (B7-2); CD247 (CD3ζ); CTLA4 (CD152); ELK1; ERK1 (MAPK3); ERK2; FOS; FYN; GRAP2 (GADS); GRB2; HLA-DRA; HLA-DRB1; HLA-DRB3; HLA-DRB4; HLA-DRB5; HRAS; IKBKA (CHUK); IKBKB; IKBKE; IKBKG (NEMO); IL2; ITPR1; ITK; JUN; KRAS2; LAT; LCK; MAP2K1 (MEK1); MAP2K2 (MEK2); MAP2K3 (MKK3); MAP2K4 (MKK4); MAP2K6 (MKK6); MAP2K7 (MKK7); MAP3K1 (MEKK1); MAP3K3; MAP3K4; MAP3K5; MAP3K8; MAP3K14 (NIK); MAPK8 (JNK1); MAPK9 (JNK2); MAPK10 (JNK3); MAPK11 (p38β); MAPK12 (p38γ); MAPK13 (p38δ); MAPK14 (p38a); NCK; NFAT1; NFAT2; NFKB1; NFKB2; NFKBIA; NRAS; PAK1; PAK2; PAK3; PAK4; PIK3C2B; PIK3C3 (VPS34); PIK3CA; PIK3CB; PIK3CD; PIK3R1; PKCA; PKCB; PKCM; PKCQ; PLCY1; PRF1 (Perforin); PTEN; RAC1; RAF1; RELA; SDF1; SHP2; SLP76; SOS; SRC; TBK1; TCRA; TEC; TRAF6; VAV1; VAV2; or ZAP70.

In some embodiments, the antigen binding domain of the CAR targets an antigen characteristic of a disorder. In some embodiments, the disease or disorder is associates with CD4+ T cells. In some embodiments, the disease or disorder is associated with CD8+ T cells.

In some embodiments, the CAR transmembrane domain comprises at least a transmembrane region of the alpha, beta or zeta chain of a T cell receptor, CD28, CD3 epsilon, CD45, CD4, CD5, CD8, CD9, CD16, CD22, CD33, CD37, CD64, CD80, CD86, CD134, CD137, CD154, or functional variant thereof. In some embodiments, the transmembrane domain comprises at least a transmembrane region(s) of CD8α, CD8β, 4-1BB/CD137, CD28, CD34, CD4, FcεRIγ, CD16, OX40/CD134, CD3ζ, CD3ε, CD3γ, CD3δ, TCRα, TCRβ, TCRζ, CD32, CD64, CD64, CD45, CD5, CD9, CD22, CD37, CD80, CD86, CD40, CD40L/CD154, VEGFR2, FAS, and FGFR2B, or functional variant thereof.

In some embodiments, the CAR comprises at least one signaling domain selected from one or more of B7-1/CD80; B7-2/CD86; B7-H1/PD-L1; B7-H2; B7-H3; B7-H4; B7-H6; B7-H7; BTLA/CD272; CD28; CTLA-4; Gi24/VISTA/B7-H5; ICOS/CD278; PD-1; PD-L2/B7-DC; PDCD6); 4-1BB/TNFSF9/CD137; 4-1BB Ligand/TNFSF9; BAFF/BLyS/TNFSF13B; BAFF R/TNFRSF13C; CD27/TNFRSF7; CD27 Ligand/TNFSF7; CD30/TNFRSF8; CD30 Ligand/TNFSF8; CD40/TNFRSF5; CD40/TNFSF5; CD40 Ligand/TNFSF5; DR3/TNFRSF25; GITR/TNFRSF18; GITR Ligand/TNFSF18; HVEM/TNFRSF14; LIGHT/TNFSF14; Lymphotoxin-alpha/TNF-beta; OX40/TNFRSF4; OX40 Ligand/TNFSF4; RELT/TNFRSF19L; TACI/TNFRSF13B; TL1A/TNFSF15; TNF-alpha; TNF RII/TNFRSF1B); 2B4/CD244/SLAMF4; BLAME/SLAMF8; CD2; CD2F-10/SLAMF9; CD48/SLAMF2; CD58/LFA-3; CD84/SLAMF5; CD229/SLAMF3; CRACC/SLAMF7; NTB-A/SLAMF6; SLAM/CD150); CD2; CD7; CD53; CD82/Kai-1; CD90/Thy1; CD96; CD160; CD200; CD300a/LMIR1; HLA Class I; HLA-DR; Ikaros; Integrin alpha 4/CD49d; Integrin alpha 4 beta 1; Integrin alpha 4 beta 7/LPAM-1; LAG-3; TCL1A; TCL1B; CRTAM; DAP12; Dectin-1/CLEC7A; DPPIV/CD26; EphB6; TIM-1/KIM-1/HAVCR; TIM-4; TSLP; TSLP R; lymphocyte function associated antigen-1 (LFA-1); NKG2C, a CD3 zeta domain, an immunoreceptor tyrosine-based activation motif (ITAM), CD27, CD28, 4-1BB, CD134/OX40, CD30, CD40, PD-1, ICOS, lymphocyte function-associated antigen-1 (LFA-1), CD2, CD7, LIGHT, NKG2C, B7-H3, a ligand that specifically binds with CD83, or functional fragment thereof.

In some embodiments, the CAR comprises a CD3 zeta domain or an immunoreceptor tyrosine-based activation motif (ITAM), or functional variant thereof. In some embodiments, the CAR comprises (i) a CD3 zeta domain, or an immunoreceptor tyrosine-based activation motif (ITAM), or functional variant thereof; and (ii) a CD28 domain, or a 4-1BB domain, or functional variant thereof. In some embodiments, the CAR comprises a (i) a CD3 zeta domain, or an immunoreceptor tyrosine-based activation motif (ITAM), or functional variant thereof; (ii) a CD28 domain or functional variant thereof; and (iii) a 4-1BB domain, or a CD134 domain, or functional variant thereof. In some embodiments, the CAR comprises (i) a CD3 zeta domain, or an immunoreceptor tyrosine-based activation motif (ITAM), or functional variant thereof; (ii) a CD28 domain, or a 4-1BB domain, or functional variant thereof, and/or (iii) a 4-1BB domain, or a CD134 domain, or functional variant thereof. In some embodiments, the CAR comprises a (i) a CD3 zeta domain, or an immunoreceptor tyrosine-based activation motif (ITAM), or functional variant thereof; (ii) a CD28 domain or functional variant thereof; (iii) a 4-1BB domain, or a CD134 domain, or functional variant thereof; and (iv) a cytokine or costimulatory ligand transgene.

In certain embodiments, the intracellular signaling domain comprises a CD28 transmembrane and signaling domain linked to a CD3 (e.g., CD3-zeta) intracellular domain. In some embodiments, the intracellular signaling domain comprises a chimeric CD28 and CD137 (4-1BB, TNFRSF9) co-stimulatory domains, linked to a CD3 zeta intracellular domain

In some embodiments, the CAR encompasses one or more, e.g., two or more, costimulatory domains and an activation domain, e.g., primary activation domain, in the cytoplasmic portion. Exemplary CARs include intracellular components of CD3-zeta, CD28, and 4-1BB.

In some embodiments the intracellular signaling domain includes intracellular components of a 4-1BB signaling domain and a CD3-zeta signaling domain. In some embodiments, the intracellular signaling domain includes intracellular components of a CD28 signaling domain and a CD3zeta signaling domain.

In some embodiments, the CAR comprises an extracellular antigen binding domain (e.g., antibody or antibody fragment, such as an scFv) that binds to an antigen (e.g. tumor antigen), a spacer (e.g. containing a hinge domain, such as any as described herein), a transmembrane domain (e.g. any as described herein), and an intracellular signaling domain (e.g. any intracellular signaling domain, such as a primary signaling domain or costimulatory signaling domain as described herein). In some embodiments, the intracellular signaling domain is or includes a primary cytoplasmic signaling domain. In some embodiments, the intracellular signaling domain additionally includes an intracellular signaling domain of a costimulatory molecule (e.g., a costimulatory domain). Examples of exemplary components of a CAR are described in Table 6. In provided aspects, the sequences of each component in a CAR can include any combination listed in Table 6.

TABLE 6 CAR components and Exemplary Sequences SEQ ID Component Sequence NO Extracellular binding domain Anti-CD19 DIQMTQTTSSLSASLGDRVTISCRASQDISKY 419 scFv (FMC63) LNWYQQKPDGTVKLLIYHTSRLHSGVPSRFS GSGSGTDYSLTISNLEQEDIATYFCQQGNTLP YTFGGGTKLEITGSTSGSGKPGSGEGSTKGE VKLQESGPGLVAPSQSLSVTCTVSGVSLPDY GVSWIRQPPRKGLEWLGVIWGSETTYYNSA LKSRLTIIKDNSKSQVFLKMNSLQTDDTAIYY CAKHYYYGGSYAMDYWGQGTSVTVSS Anti-CD19 DIQMTQTTSSLSASLGDRVTISCRASQDISKY 420 scFv (FMC63) LNWYQQKPDGTVKLLIYHTSRLHSGVPSRFS GSGSGTDYSLTISNLEQEDIATYFCQQGNTLP YTFGGGTKLEITGGGGSGGGGSGGGGSEVK LQESGPGLVAPSQSLSVTCTVSGVSLPDYGV SWIRQPPRKGLEWLGVIWGSETTYYNSALKS RLTIIKDNSKSQVFLKMNSLQTDDTAIYYCA KHYYYGGSYAMDYWGQGTSVTVSS Spacer (e.g. hinge) IgG4 Hinge ESKYGPPCPPCP 421 CD8 Hinge TTTPAPRPPTPAPTIASQPLSLRPE 422 CD28 IEVMYPPPYLDNEKSNGTIIHVKGKHLCPSPL 423 FPGPSKP Transmembrane CD8 ACRPAAGGAVHTRGLDFACDIYIWAPLAGT 424 CGVLLLSLVITLYC CD28 FWVLVVVGGVLACYSLLVTVAFIIFWV 425 CD28 FWVLVVVGGVLACYSLLVTVAFIIFWV 426 Costimulatory domain CD28 RSKRSRLLHSDYMNMTPRRPGPTRKHYQPY 427 APPRDFAAYRS 4-1BB KRGRKKLLYIFKQPFMRPVQTTQEEDGCSCR 428 FPEEEEGGCEL Primary Signaling Domain CD3zeta RVKFSRSADAPAYQQGQNQLYNELNLGRRE 429 EYDVLDKRRGRDPEMGGKPRRKNPQEGLY NELQKDKMAEAYSEIGMKGERRRGKGHDG LYQGLSTATKDTYDALHMQALPPR CD3zeta RVKFSRSADAPAYKQGQNQLYNELNLGRRE 430 EYDVLDKRRGRDPEMGGKPRRKNPQEGLY NELQKDKMAEAYSEIGMKGERRRGKGHDG LYQGLSTATKDTYDALHMQALPPR

In some embodiments, the CAR further comprises one or more spacers, e.g., wherein the spacer is a first spacer between the antigen binding domain and the transmembrane domain. In some embodiments, the first spacer includes at least a portion of an immunoglobulin constant region or variant or modified version thereof. In some embodiments, the spacer is a second spacer between the transmembrane domain and a signaling domain. In some embodiments, the second spacer is an oligopeptide, e.g., wherein the oligopeptide comprises glycine-serine doublets.

In addition to the CARs described herein, various chimeric antigen receptors and nucleotide sequences encoding the same are known and would be suitable for fusosomal delivery and reprogramming of target cells in vivo and in vitro as described herein. See, e.g., WO2013040557; WO2012079000; WO2016030414; Smith T, et al., Nature Nanotechnology. 2017. (DOI: 10.1038/NNANO.2017.57), the disclosures of which are herein incorporated by reference in their entirety.

In some embodiments a targeted lipid particle comprising a CAR or a nucleic acid encoding a CAR (e.g., a DNA, a gDNA, a cDNA, an RNA, a pre-MRNA, an mRNA, an miRNA, an siRNA, etc.) is delivered to a target cell. In some embodiments the target cell is an effector cell, e.g., a cell of the immune system that expresses one or more Fc receptors and mediates one or more effector functions. In some embodiments, a target cell may include, but may not be limited to, one or more of a monocyte, macrophage, neutrophil, dendritic cell, eosinophil, mast cell, platelet, large granular lymphocyte, Langerhans' cell, natural killer (NK) cell, T lymphocyte (e.g., T cell), a Gamma delta T cell, B lymphocyte (e.g., B cell) and may be from any organism including but not limited to humans, mice, rats, rabbits, and monkeys.

E. Methods of Generating Targeted Lipid Particles

Provided herein is a targeted lipid particle comprising a lipid bilayer, a lumen surrounded by the lipid bilayer, a targeted envelope protein, and a fusogen, in which the targeted envelope protein and fusogen are embedded within the lipid bilayer. In some embodiments, the targeted lipid particle can be a viral particle, a virus-like particle, a nanoparticle, a vesicle, an exosome, a dendrimer, a lentivirus, a viral vector, an enucleated cell, a microvesicle, a membrane vesicle, an extracellular membrane vesicle, a plasma membrane vesicle, a giant plasma membrane vesicle, an apoptotic body, a mitoparticle, a pyrenocyte, a lysosome, another membrane enclosed vesicle, or a lentiviral vector, a viral based particle, a virus like particle (VLP) or a cell derived particle.

I. Virus-Like Particles

Provided herein are targeted lipid particles that are derived from virus, such as viral particles or virus-like particles, including those derived from retroviruses or lentiviruses. In some embodiments, the targeted lipid particle's bilayer of amphipathic lipids is or comprises the viral envelope. In some embodiments, the targeted lipid particle's bilayer of amphipathic lipids is or comprises lipids derived from a producer cell. In some embodiments, the viral envelope may comprise a fusogen, e.g., a fusogen that is endogenous to the virus or a pseudotyped fusogen. In some embodiments, the targeted lipid particle's lumen or cavity comprises a viral nucleic acid, e.g., a retroviral nucleic acid, e.g., a lentiviral nucleic acid. In some embodiments, the viral nucleic acid may be a viral genome. In some embodiments, the targeted lipid particle further comprises one or more viral non-structural proteins, e.g., in its cavity or lumen. In some embodiments, the targeted lipid particles is or comprises a virus-like particle (VLP). In some embodiments, the VLP does not comprise an envelope. In some embodiments, the VLP comprises an envelope.

In some embodiments, the viral particle or virus-like particle, such as retrovirus or retrovirus-like particle, comprises one or more of gag polyprotein, polymerase (e.g., pol), integrase (e.g., a functional or non-functional variant), protease, and a fusogen. In some embodiments, the targeted lipid particle further comprises rev. In some embodiments, one or more of the aforesaid proteins are encoded in the retroviral genome, and in some embodiments, one or more of the aforesaid proteins are provided in trans, e.g., by a helper cell, helper virus, or helper plasmid. In some embodiments, the targeted lipid particle nucleic acid (e.g., retroviral nucleic acid) comprises one or more of the following nucleic acid sequences: 5′ LTR (e.g., comprising U5 and lacking a functional U3 domain), Psi packaging element (Psi), Central polypurine tract (cPPT) Promoter operatively linked to the payload gene, payload gene (optionally comprising an intron before the open reading frame), Poly A tail sequence, WPRE, and 3′ LTR (e.g., comprising U5 and lacking a functional U3). In some embodiments the targeted lipid particle nucleic acid further comprises one or more insulator element. In some embodiments, the recognition sites are situated between the poly A tail sequence and the WPRE.

In some embodiments, the targeted lipid particle comprises supramolecular complexes formed by viral proteins that self-assemble into capsids. In some embodiments, the targeted lipid particle is a viral particle or virus-like particle derived from viral capsids. In some embodiments, the targeted lipid particle is a viral particle or virus-like particle derived from viral nucleocapsids. In some embodiments, the targeted lipid particle comprises nucleocapsid-derived that retain the property of packaging nucleic acids. In some embodiments, the viral particles or virus-like particles comprises only viral structural glycoproteins. In some embodiments, the targeted lipid particle does not contain a viral genome.

In some embodiments, the targeted lipid particle packages nucleic acids from host cells during the expression process. In some embodiments, the nucleic acids do not encode any genes involved in virus replication. In particular embodiments, the targeted lipid particle is a virus-like particle, e.g. retrovirus-like particle such as a lentivirus-like particle, that is replication defective.

In some cases, the targeted lipid particle is a viral particle that is morphologically indistinguishable from the wild type infectious virus. In some embodiments, the viral particle presents the entire viral proteome as an antigen. In some embodiments, the viral particle presents only a portion of the proteome as an antigen.

In some embodiments, the viral particle or virus-like particle is produced utilizing proteins (e.g., envelope proteins) from a virus within the Paramyxoviridae family In some embodiments, the Paramyxoviridae family comprises members within the Henipavirus genus. In some embodiments, the Henipavirus is or comprises a Hendra (HeV) or a Nipah (NiV) virus. In particular embodiments, the viral particles or virus-like particles incorporate a targeted envelope protein and fusogen as described in Section I.A. and 1.B.

In some embodiments, viral particles or virus-like particles may be produced in multiple cell culture systems including bacteria, mammalian cell lines, insect cell lines, yeast and plant cells.

In some embodiments, the assembly of a viral particle or virus-like particle is initiated by binding of the core protein to a unique encapsidation sequence within the viral genome (e.g. UTR with stem-loop structure). In some embodiments, the interaction of the core with the encapsidation sequence facilitates oligomerization.

In some embodiments, the targeted lipid particle is a virus-like particle which comprises a sequence that is devoid of or lacking viral RNA may be the result of removing or eliminating the viral RNA from the sequence. In some embodiments, this may be achieved by using an endogenous packaging signal binding site on gag. In some embodiments, the endogenous packaging signal binding site is on pol. In some embodiments, the RNA which is to be delivered will contain a cognate packaging signal. In some embodiments, a heterologous binding domain (which is heterologous to gag) located on the RNA to be delivered, and a cognate binding site located on gag or pol, can be used to ensure packaging of the RNA to be delivered. In some embodiments, the heterologous sequence could be non-viral or it could be viral, in which case it may be derived from a different virus. In some embodiments, the vector particles could be used to deliver therapeutic RNA, in which case functional integrase and/or reverse transcriptase is not required. In some embodiments, the vector particles could also be used to deliver a therapeutic gene of interest, in which case pol is typically included.

a. Transfer Vectors

In some embodiments, the retroviral nucleic acid comprises one or more of (e.g., all of): a 5′ promoter (e.g., to control expression of the entire packaged RNA), a 5′ LTR (e.g., that includes R (polyadenylation tail signal) and/or U5 which includes a primer activation signal), a primer binding site, a psi packaging signal, a RRE element for nuclear export, a promoter directly upstream of the transgene to control transgene expression, a transgene (or other exogenous agent element), a polypurine tract, and a 3′ LTR (e.g., that includes a mutated U3, a R, and U5). In some embodiments, the retroviral nucleic acid further comprises one or more of a cPPT, a WPRE, and/or an insulator element.

A retrovirus typically replicates by reverse transcription of its genomic RNA into a linear double-stranded DNA copy and subsequently covalently integrates its genomic DNA into a host genome. Illustrative retroviruses suitable for use in particular embodiments, include, but are not limited to: Moloney murine leukemia virus (M-MuLV), Moloney murine sarcoma virus (MoMSV), Harvey murine sarcoma virus (HaMuSV), murine mammary tumor virus (MuMTV), gibbon ape leukemia virus (GaLV), feline leukemia virus (FLV), spumavirus, Friend murine leukemia virus, Murine Stem Cell Virus (MSCV) and Rous Sarcoma Virus (RSV), and lentivirus.

In some embodiments the retrovirus is a Gammaretrovirus. In some embodiments the retrovirus is an Epsilonretrovirus. In some embodiments the retrovirus is an Alpharetrovirus. In some embodiments the retrovirus is a Betaretrovirus. In some embodiments the retrovirus is a Deltaretrovirus. In some embodiments the retrovirus is a Lentivirus. In some embodiments the retrovirus is a Spumaretrovirus. In some embodiments the retrovirus is an endogenous retrovirus.

Illustrative lentiviruses include, but are not limited to: HIV (human immunodeficiency virus; including HIV type 1, and HIV type 2); visna-maedi virus (VMV) virus; the caprine arthritis-encephalitis virus (CAEV); equine infectious anemia virus (EIAV); feline immunodeficiency virus (FIV); bovine immune deficiency virus (BIV); and simian immunodeficiency virus (SIV). In some embodiments, HIV based vector backbones (i.e., HIV cis-acting sequence elements) are used.

In some embodiments, a vector herein is a nucleic acid molecule capable transferring or transporting another nucleic acid molecule. The transferred nucleic acid is generally linked to, e.g., inserted into, the vector nucleic acid molecule. A vector may include sequences that direct autonomous replication in a cell, or may include sequences sufficient to allow integration into host cell DNA. Useful vectors include, for example, plasmids (e.g., DNA plasmids or RNA plasmids), transposons, cosmids, bacterial artificial chromosomes, and viral vectors. Useful viral vectors include, e.g., replication defective retroviruses and lentiviruses.

In some embodiments, a viral vector comprises a nucleic acid molecule (e.g., a transfer plasmid) that includes virus-derived nucleic acid elements that typically facilitate transfer of the nucleic acid molecule or integration into the genome of a cell or to a viral particle that mediates nucleic acid transfer. Viral particles will typically include various viral components and sometimes also host cell components in addition to nucleic acid(s). In some embodiments, a viral vector comprises e.g., a virus or viral particle capable of transferring a nucleic acid into a cell, or to the transferred nucleic acid (e.g., as naked DNA). In some embodiments, a viral vectors and transfer plasmids comprise structural and/or functional genetic elements that are primarily derived from a virus. A retroviral vector can comprise a viral vector or plasmid containing structural and functional genetic elements, or portions thereof, that are primarily derived from a retrovirus. A lentiviral vector can comprise a viral vector or plasmid containing structural and functional genetic elements, or portions thereof, including LTRs that are primarily derived from a lentivirus.

In embodiments, a lentiviral vector (e.g., lentiviral expression vector) may comprise a lentiviral transfer plasmid (e.g., as naked DNA) or an infectious lentiviral particle. With respect to elements such as cloning sites, promoters, regulatory elements, heterologous nucleic acids, etc., it is to be understood that the sequences of these elements can be present in RNA form in lentiviral particles and can be present in DNA form in DNA plasmids.

In some embodiments, in the vectors described herein at least part of one or more protein coding regions that contribute to or are essential for replication may be absent compared to the corresponding wild-type virus. In some embodiments, the viral vector replication-defective. In some embodiments, the vector is capable of transducing a target non-dividing host cell and/or integrating its genome into a host genome.

In some embodiments, the structure of a wild-type retrovirus genome often comprises a 5′ long terminal repeat (LTR) and a 3′ LTR, between or within which are located a packaging signal to enable the genome to be packaged, a primer binding site, integration sites to enable integration into a host cell genome and gag, pol and env genes encoding the packaging components which promote the assembly of viral particles. More complex retroviruses have additional features, such as rev and RRE sequences in HIV, which enable the efficient export of RNA transcripts of the integrated provirus from the nucleus to the cytoplasm of an infected target cell. In the provirus, the viral genes are flanked at both ends by regions called long terminal repeats (LTRs). In some embodiments, the LTRs are involved in proviral integration and transcription. In some embodiments, LTRs serve as enhancer-promoter sequences and can control the expression of the viral genes. In some embodiments, encapsidation of the retroviral RNAs occurs by virtue of a psi sequence located at the 5′ end of the viral genome.

In some embodiments, LTRs are similar sequences that can be divided into three elements, which are called U3, R and U5. U3 is derived from the sequence unique to the 3′ end of the RNA. R is derived from a sequence repeated at both ends of the RNA and U5 is derived from the sequence unique to the 5′ end of the RNA. The sizes of the three elements can vary considerably among different retroviruses.

In some embodiments, for the viral genome, the site of transcription initiation is typically at the boundary between U3 and R in one LTR and the site of poly (A) addition (termination) is at the boundary between R and U5 in the other LTR. U3 contains most of the transcriptional control elements of the provirus, which include the promoter and multiple enhancer sequences responsive to cellular and in some cases, viral transcriptional activator proteins. In some embodiments, retroviruses comprise any one or more of the following genes that code for proteins that are involved in the regulation of gene expression: tat, rev, tax and rex.

In some embodiments, the structural genes gag, pol and env, gag encodes the internal structural protein of the virus. In some embodiments, Gag protein is proteolytically processed into the mature proteins MA (matrix), CA (capsid) and NC (nucleocapsid). In some embodiments, the pol gene encodes the reverse transcriptase (RT), which contains DNA polymerase, associated RNase H and integrase (IN), which mediate replication of the genome. In some embodiments, the env gene encodes the surface (SU) glycoprotein and the transmembrane (TM) protein of the virion, which form a complex that interacts specifically with cellular receptor proteins. In some embodiments, the interaction promotes infection by fusion of the viral membrane with the cell membrane.

In some embodiments, a replication-defective retroviral vector genome gag, pol and env may be absent or not functional. In some embodiments, the R regions at both ends of the RNA are typically repeated sequences. In some embodiments, U5 and U3 represent unique sequences at the 5′ and 3′ ends of the RNA genome respectively.

In some embodiments, retroviruses may also contain additional genes which code for proteins other than gag, pol and env. Examples of additional genes include (in HIV), one or more of vif, vpr, vpx, vpu, tat, rev and nef. EIAV has (amongst others) the additional gene S2. In some embodiments, proteins encoded by additional genes serve various functions, some of which may be duplicative of a function provided by a cellular protein. In EIAV, for example, tat acts as a transcriptional activator of the viral LTR (Derse and Newbold 1993 Virology 194:530-6; Maury et al. 1994 Virology 200:632-42). It binds to a stable, stem-loop RNA secondary structure referred to as TAR. Rev regulates and co-ordinates the expression of viral genes through rev-response elements (RRE) (Martarano et al. 1994 J. Virol. 68:3102-11).

In some embodiments, in addition to protease, reverse transcriptase and integrase, non-primate lentiviruses contain a fourth pol gene product which codes for a dUTPase. In some embodiments, this a role in the ability of these lentiviruses to infect certain non-dividing or slowly dividing cell types.

In embodiments, a recombinant lentiviral vector (RLV) is a vector with sufficient retroviral genetic information to allow packaging of an RNA genome, in the presence of packaging components, into a viral particle capable of infecting a target cell. In some embodiments, infection of the target cell can comprise reverse transcription and integration into the target cell genome. In some embodiments, the RLV typically carries non-viral coding sequences which are to be delivered by the vector to the target cell. In some embodiments, an RLV is incapable of independent replication to produce infectious retroviral particles within the target cell. In some embodiments, the RLV lacks a functional gag-pol and/or env gene and/or other genes involved in replication. In some embodiments, the vector may be configured as a split-intron vector, e.g., as described in PCT patent application WO 99/15683, which is herein incorporated by reference in its entirety.

In some embodiments, the lentiviral vector comprises a minimal viral genome, e.g., the viral vector has been manipulated so as to remove the non-essential elements and to retain the essential elements in order to provide the required functionality to infect, transduce and deliver a nucleotide sequence of interest to a target host cell, e.g., as described in WO 98/17815, which is herein incorporated by reference in its entirety.

In some embodiments, a minimal lentiviral genome may comprise, e.g., (5′)R-U5-one or more first nucleotide sequences-U3-R(3′). In some embodiments, the plasmid vector used to produce the lentiviral genome within a source cell can also include transcriptional regulatory control sequences operably linked to the lentiviral genome to direct transcription of the genome in a source cell. In some embodiments, the regulatory sequences may comprise the natural sequences associated with the transcribed retroviral sequence, e.g., the 5′ U3 region, or they may comprise a heterologous promoter such as another viral promoter, for example the CMV promoter. In some embodiments, lentiviral genomes comprise additional sequences to promote efficient virus production. In some embodiments, in the case of HIV, rev and RRE sequences may be included. In some embodiments, alternatively or combination, codon optimization may be used, e.g., the gene encoding the exogenous agent may be codon optimized, e.g., as described in WO 01/79518, which is herein incorporated by reference in its entirety. In some embodiments, alternative sequences which perform a similar or the same function as the rev/RRE system may also be used. In some embodiments, a functional analogue of the rev/RRE system is found in the Mason Pfizer monkey virus. In some embodiments, this is known as CTE and comprises an RRE-type sequence in the genome which is believed to interact with a factor in the infected cell. The cellular factor can be thought of as a rev analogue. In some embodiments, CTE may be used as an alternative to the rev/RRE system. In some embodiments, the Rex protein of HTLV-I can functionally replace the Rev protein of HIV-I. Rev and Rex have similar effects to IRE-BP.

In some embodiments, a retroviral nucleic acid (e.g., a lentiviral nucleic acid, e.g., a primate or non-primate lentiviral nucleic acid) (1) comprises a deleted gag gene wherein the deletion in gag removes one or more nucleotides downstream of about nucleotide 350 or 354 of the gag coding sequence; (2) has one or more accessory genes absent from the retroviral nucleic acid; (3) lacks the tat gene but includes the leader sequence between the end of the 5′ LTR and the ATG of gag; and (4) combinations of (1), (2) and (3). In an embodiment the lentiviral vector comprises all of features (1) and (2) and (3). This strategy is described in more detail in WO 99/32646, which is herein incorporated by reference in its entirety.

In some embodiments, a primate lentivirus minimal system requires none of the HIV/SIV additional genes vif, vpr, vpx, vpu, tat, rev and nef for either vector production or for transduction of dividing and non-dividing cells. In some embodiments, an EIAV minimal vector system does not require S2 for either vector production or for transduction of dividing and non-dividing cells.

In some embodiments, the deletion of additional genes may permit vectors to be produced without the genes associated with disease in lentiviral (e.g. HIV) infections. In some embodiments, tat is associated with disease. In some embodiments, the deletion of additional genes permits the vector to package more heterologous DNA. In some embodiments, genes whose function is unknown, such as S2, may be omitted, thus reducing the risk of causing undesired effects. Examples of minimal lentiviral vectors are disclosed in WO 99/32646 and in WO 98/17815.

In some embodiments, the retroviral nucleic acid is devoid of at least tat and S2 (if it is an EIAV vector system), and possibly also vif, vpr, vpx, vpu and nef. In some embodiments, the retroviral nucleic acid is also devoid of rev, RRE, or both.

In some embodiments the retroviral nucleic acid comprises vpx. The Vpx polypeptide binds to and induces the degradation of the SAMHD1 restriction factor, which degrades free dNTPs in the cytoplasm. In some embodiments, the concentration of free dNTPs in the cytoplasm increases as Vpx degrades SAMHD1 and reverse transcription activity is increased, thus facilitating reverse transcription of the retroviral genome and integration into the target cell genome.

In some embodiments, different cells differ in their usage of particular codons. In some embodiments, this codon bias corresponds to a bias in the relative abundance of particular tRNAs in the cell type. In some embodiments, by altering the codons in the sequence so that they are tailored to match with the relative abundance of corresponding tRNAs, it is possible to increase expression. In some embodiments, it is possible to decrease expression by deliberately choosing codons for which the corresponding tRNAs are known to be rare in the particular cell type. In some embodiments, an additional degree of translational control is available. An additional description of codon optimization is found, e.g., in WO 99/41397, which is herein incorporated by reference in its entirety.

In some embodiments viruses, including HIV and other lentiviruses, use a large number of rare codons and by changing these to correspond to commonly used mammalian codons, increased expression of the packaging components in mammalian producer cells can be achieved.

In some embodiments, codon optimization has a number of other advantages. In some embodiments, by virtue of alterations in their sequences, the nucleotide sequences encoding the packaging components may have RNA instability sequences (INS) reduced or eliminated from them. At the same time, the amino acid sequence coding sequence for the packaging components is retained so that the viral components encoded by the sequences remain the same, or at least sufficiently similar that the function of the packaging components is not compromised. In some embodiments, codon optimization also overcomes the Rev/RRE requirement for export, rendering optimized sequences Rev independent. In some embodiments, codon optimization also reduces homologous recombination between different constructs within the vector system (for example between the regions of overlap in the gag-pol and env open reading frames). In some embodiments, codon optimization leads to an increase in viral titer and/or improved safety.

In some embodiments, only codons relating to INS are codon optimized. In other embodiments, the sequences are codon optimized in their entirety, with the exception of the sequence encompassing the frameshift site of gag-pol.

The gag-pol gene comprises two overlapping reading frames encoding the gag-pol proteins. The expression of both proteins depends on a frameshift during translation. This frameshift occurs as a result of ribosome “slippage” during translation. This slippage is thought to be caused at least in part by ribosome-stalling RNA secondary structures. Such secondary structures exist downstream of the frameshift site in the gag-pol gene. For HIV, the region of overlap extends from nucleotide 1222 downstream of the beginning of gag (wherein nucleotide 1 is the A of the gag ATG) to the end of gag (nt 1503). Consequently, a 281 bp fragment spanning the frameshift site and the overlapping region of the two reading frames is preferably not codon optimized. In some embodiments, retaining this fragment will enable more efficient expression of the gag-pol proteins. For EIAV, the beginning of the overlap is at nt 1262 (where nucleotide 1 is the A of the gag ATG). The end of the overlap is at nt 1461. In order to ensure that the frameshift site and the gag-pol overlap are preserved, the wild type sequence may be retained from nt 1156 to 1465.

In some embodiments, derivations from optimal codon usage may be made, for example, in order to accommodate convenient restriction sites, and conservative amino acid changes may be introduced into the gag-pol proteins.

In some embodiments, codon optimization is based on codons with poor codon usage in mammalian systems. The third and sometimes the second and third base may be changed.

In some embodiments, due to the degenerate nature of the genetic code, it will be appreciated that numerous gag-pol sequences can be achieved by a skilled worker. Also, there are many retroviral variants described which can be used as a starting point for generating a codon optimized gag-pol sequence. Lentiviral genomes can be quite variable. For example there are many quasi-species of HIV-I which are still functional. This is also the case for EIAV. These variants may be used to enhance particular parts of the transduction process. Examples of HIV-I variants may be found in the HIV databases maintained by Los Alamos National Laboratory. Details of EIAV clones may be found at the NCBI database maintained by the National Institutes of Health.

In some embodiments, the strategy for codon optimized gag-pol sequences can be used in relation to any retrovirus, e.g., EIAV, FIV, BIV, CAEV, VMR, SIV, HIV-I and HIV-2. In addition this method could be used to increase expression of genes from HTLV-I, HTLV-2, HFV, HSRV and human endogenous retroviruses (HERV), MLV and other retroviruses.

In embodiments, the retroviral vector comprises a packaging signal that comprises from 255 to 360 nucleotides of gag in vectors that still retain env sequences, or about 40 nucleotides of gag in a particular combination of splice donor mutation, gag and env deletions. In some embodiments, the retroviral vector includes a gag sequence which comprises one or more deletions, e.g., the gag sequence comprises about 360 nucleotides derivable from the N-terminus.

In some embodiments, the retroviral vector, helper cell, helper virus, or helper plasmid may comprise retroviral structural and accessory proteins, for example gag, pol, env, tat, rev, vif, vpr, vpu, vpx, or nef proteins or other retroviral proteins. In some embodiments the retroviral proteins are derived from the same retrovirus. In some embodiments the retroviral proteins are derived from more than one retrovirus, e.g. 2, 3, 4, or more retroviruses.

In some embodiments, the gag and pol coding sequences are generally organized as the Gag-Pol Precursor in native lentivirus. The gag sequence codes for a 55-kD Gag precursor protein, also called p55. The p55 is cleaved by the virally encoded protease (a product of the pol gene) during the process of maturation into four smaller proteins designated MA (matrix [p17]), CA (capsid [p24]), NC (nucleocapsid [p9]), and p6. The pol precursor protein is cleaved away from Gag by a virally encoded protease, and further digested to separate the protease (p10), RT (p50), RNase H (p15), and integrase (p31) activities.

In some embodiments, the lentiviral vector is integration-deficient. In some embodiments, the pol is integrase deficient, such as by encoding due to mutations in the integrase gene. For example, the pol coding sequence can contain an inactivating mutation in the integrase, such as by mutation of one or more of amino acids involved in catalytic activity, i.e. mutation of one or more of aspartic 64, aspartic acid 116 and/or glutamic acid 152. In some embodiments, the integrase mutation is a D64V mutation. In some embodiments, the mutation in the integrase allows for packaging of viral RNA into a lentivirus. In some embodiments, the mutation in the integrase allows for packaging of viral proteins into a letivirus. In some embodiments, the mutation in the integrase reduces the possibility of insertional mutagenesis. In some embodiments, the mutation in the integrase decreases the possibility of generating replication-competent recombinants (RCRs) (Wanisch et al. 2009. Mol Ther. 1798):1316-1332). In some embodiments, native Gag-Pol sequences can be utilized in a helper vector (e.g., helper plasmid or helper virus), or modifications can be made. These modifications include, chimeric Gag-Pol, where the Gag and Pol sequences are obtained from different viruses (e.g., different species, subspecies, strains, clades, etc.), and/or where the sequences have been modified to improve transcription and/or translation, and/or reduce recombination.

In some embodiments, the retroviral nucleic acid includes a polynucleotide encoding a 150-250 (e.g., 168) nucleotide portion of a gag protein that (i) includes a mutated INS1 inhibitory sequence that reduces restriction of nuclear export of RNA relative to wild-type INS1, (ii) contains two nucleotide insertion that results in frame shift and premature termination, and/or (iii) does not include INS2, INS3, and INS4 inhibitory sequences of gag.

In some embodiments, a vector described herein is a hybrid vector that comprises both retroviral (e.g., lentiviral) sequences and non-lentiviral viral sequences. In some embodiments, a hybrid vector comprises retroviral e.g., lentiviral, sequences for reverse transcription, replication, integration and/or packaging.

In some embodiments, most or all of the viral vector backbone sequences are derived from a lentivirus, e.g., HIV-1. However, it is to be understood that many different sources of retroviral and/or lentiviral sequences can be used or combined and numerous substitutions and alterations in certain of the lentiviral sequences may be accommodated without impairing the ability of a transfer vector to perform the functions described herein. A variety of lentiviral vectors are described in Naldini et al., (1996a, 1996b, and 1998); Zufferey et al., (1997); Dull et al., 1998, U.S. Pat. Nos. 6,013,516; and 5,994,136, many of which may be adapted to produce a retroviral nucleic acid.

In some embodiments, at each end of the provirus, long terminal repeats (LTRs) are typically found. An LTR typically comprises a domain located at the ends of retroviral nucleic acid which, in their natural sequence context, are direct repeats and contain U3, R and U5 regions. LTRs generally promote the expression of retroviral genes (e.g., promotion, initiation and polyadenylation of gene transcripts) and viral replication. The LTR can comprise numerous regulatory signals including transcriptional control elements, polyadenylation signals and sequences for replication and integration of the viral genome. The viral LTR is typically divided into three regions called U3, R and U5. The U3 region typically contains the enhancer and promoter elements. The U5 region is typically the sequence between the primer binding site and the R region and can contain the polyadenylation sequence. The R (repeat) region can be flanked by the U3 and U5 regions. The LTR is typically composed of U3, R and U5 regions and can appear at both the 5′ and 3′ ends of the viral genome. In some embodiments, adjacent to the 5′ LTR are sequences for reverse transcription of the genome (the tRNA primer binding site) and for efficient packaging of viral RNA into particles (the Psi site).

In some embodiments, a packaging signal can comprise a sequence located within the retroviral genome which mediate insertion of the viral RNA into the viral capsid or particle, see e.g., Clever et al., 1995. J. of Virology, Vol. 69, No. 4; pp. 2101-2109. Several retroviral vectors use a minimal packaging signal (a psi NI sequence) for encapsidation of the viral genome.

In various embodiments, retroviral nucleic acids comprise modified 5′ LTR and/or 3′ LTRs. Either or both of the LTR may comprise one or more modifications including, but not limited to, one or more deletions, insertions, or substitutions. Modifications of the 3′ LTR are often made to improve the safety of lentiviral or retroviral systems by rendering viruses replication-defective, e.g., virus that is not capable of complete, effective replication such that infective virions are not produced (e.g., replication-defective lentiviral progeny).

In some embodiments, a vector is a self-inactivating (SIN) vector, e.g., replication-defective vector, e.g., retroviral or lentiviral vector, in which the right (3′) LTR enhancer-promoter region, known as the U3 region, has been modified (e.g., by deletion or substitution) to prevent viral transcription beyond the first round of viral replication. This is because the right (3′) LTR U3 region can be used as a template for the left (5′) LTR U3 region during viral replication and, thus, absence of the U3 enhancer-promoter inhibits viral replication. In embodiments, the 3′ LTR is modified such that the U5 region is removed, altered, or replaced, for example, with an exogenous poly(A) sequence The 3′ LTR, the 5′ LTR, or both 3′ and 5′ LTRs, may be modified LTRs.

In some embodiments, the U3 region of the 5′ LTR is replaced with a heterologous promoter to drive transcription of the viral genome during production of viral particles. Examples of heterologous promoters which can be used include, for example, viral simian virus 40 (SV40) (e.g., early or late), cytomegalovirus (CMV) (e.g., immediate early), Moloney murine leukemia virus (MoMLV), Rous sarcoma virus (RSV), and herpes simplex virus (HSV) (thymidine kinase) promoters. In some embodiments, promoters are able to drive high levels of transcription in a Tat-independent manner. In certain embodiments, the heterologous promoter has additional advantages in controlling the manner in which the viral genome is transcribed. For example, the heterologous promoter can be inducible, such that transcription of all or part of the viral genome will occur only when the induction factors are present. Induction factors include, but are not limited to, one or more chemical compounds or the physiological conditions such as temperature or pH, in which the host cells are cultured.

In some embodiments, viral vectors comprise a TAR (trans-activation response) element, e.g., located in the R region of lentiviral (e.g., HIV) LTRs. This element interacts with the lentiviral trans-activator (tat) genetic element to enhance viral replication. However, this element is not required, e.g., in embodiments wherein the U3 region of the 5′ LTR is replaced by a heterologous promoter.

In some embodiments, the R region, e.g., the region within retroviral LTRs beginning at the start of the capping group (i.e., the start of transcription) and ending immediately prior to the start of the poly A tract can be flanked by the U3 and U5 regions. The R region plays a role during reverse transcription in the transfer of nascent DNA from one end of the genome to the other.

In some embodiments, the retroviral nucleic acid can also comprise a FLAP element, e.g., a nucleic acid whose sequence includes the central polypurine tract and central termination sequences (cPPT and CTS) of a retrovirus, e.g., HIV-1 or HIV-2. Suitable FLAP elements are described in U.S. Pat. No. 6,682,907 and in Zennou, et al., 2000, Cell, 101:173, which are herein incorporated by reference in their entireties. During HIV-1 reverse transcription, central initiation of the plus-strand DNA at the central polypurine tract (cPPT) and central termination at the central termination sequence (CTS) can lead to the formation of a three-stranded DNA structure: the HIV-1 central DNA flap. In some embodiments, the retroviral or lentiviral vector backbones comprise one or more FLAP elements upstream or downstream of the gene encoding the exogenous agent. For example, in some embodiments a transfer plasmid includes a FLAP element, e.g., a FLAP element derived or isolated from HIV-1.

In embodiments, a retroviral or lentiviral nucleic acid comprises one or more export elements, e.g., a cis-acting post-transcriptional regulatory element which regulates the transport of an RNA transcript from the nucleus to the cytoplasm of a cell. Examples of RNA export elements include, but are not limited to, the human immunodeficiency virus (HIV) rev response element (RRE) (see e.g., Cullen et al., 1991. J. Virol. 65: 1053; and Cullen et al., 1991. Cell 58: 423), and the hepatitis B virus post-transcriptional regulatory element (HPRE), which are herein incorporated by reference in their entireties. Generally, the RNA export element is placed within the 3′ UTR of a gene, and can be inserted as one or multiple copies.

In some embodiments, expression of heterologous sequences in viral vectors is increased by incorporating one or more of, e.g., all of, posttranscriptional regulatory elements, polyadenylation sites, and transcription termination signals into the vectors. A variety of posttranscriptional regulatory elements can increase expression of a heterologous nucleic acid at the protein, e.g., woodchuck hepatitis virus posttranscriptional regulatory element (WPRE; Zufferey et al., 1999, J. Virol., 73:2886); the posttranscriptional regulatory element present in hepatitis B virus (HPRE) (Huang et al., Mol. Cell. Biol., 5:3864); and the like (Liu et al., 1995, Genes Dev., 9:1766), each of which is herein incorporated by reference in its entirety. In some embodiments, a retroviral nucleic acid described herein comprises a posttranscriptional regulatory element such as a WPRE or HPRE.

In some embodiments, a retroviral nucleic acid described herein lacks or does not comprise a posttranscriptional regulatory element such as a WPRE or HPRE.

In some embodiments, elements directing the termination and polyadenylation of the heterologous nucleic acid transcripts may be included, e.g., to increases expression of the exogenous agent. Transcription termination signals may be found downstream of the polyadenylation signal. In some embodiments, vectors comprise a polyadenylation sequence 3′ of a polynucleotide encoding the exogenous agent. A polyA site may comprise a DNA sequence which directs both the termination and polyadenylation of the nascent RNA transcript by RNA polymerase II. Polyadenylation sequences can promote mRNA stability by addition of a polyA tail to the 3′ end of the coding sequence and thus, contribute to increased translational efficiency. Illustrative examples of polyA signals that can be used in a retroviral nucleic acid, include AATAAA, ATTAAA, AGTAAA, a bovine growth hormone polyA sequence (BGHpA), a rabbit β-globin polyA sequence (rβgpA), or another suitable heterologous or endogenous polyA sequence.

In some embodiments, a retroviral or lentiviral vector further comprises one or more insulator elements, e.g., an insulator element described herein.

In various embodiments, the vectors comprise a promoter operably linked to a polynucleotide encoding an exogenous agent. The vectors may have one or more LTRs, wherein either LTR comprises one or more modifications, such as one or more nucleotide substitutions, additions, or deletions. The vectors may further comprise one of more accessory elements to increase transduction efficiency (e.g., a cPPT/FLAP), viral packaging (e.g., a Psi (Ψ) packaging signal, RRE), and/or other elements that increase exogenous gene expression (e.g., poly (A) sequences), and may optionally comprise a WPRE or HPRE.

In some embodiments, a lentiviral nucleic acid comprises one or more of, e.g., all of, e.g., from 5′ to 3′, a promoter (e.g., CMV), an R sequence (e.g., comprising TAR), a U5 sequence (e.g., for integration), a PBS sequence (e.g., for reverse transcription), a DIS sequence (e.g., for genome dimerization), a psi packaging signal, a partial gag sequence, an RRE sequence (e.g., for nuclear export), a cPPT sequence (e.g., for nuclear import), a promoter to drive expression of the exogenous agent, a gene encoding the exogenous agent, a WPRE sequence (e.g., for efficient transgene expression), a PPT sequence (e.g., for reverse transcription), an R sequence (e.g., for polyadenylation and termination), and a U5 signal (e.g., for integration).

b. Packaging Vectors and Producer Cells

Large scale viral particle production is often useful to achieve a desired viral titer. Viral particles can be produced by transfecting a transfer vector into a packaging cell line that comprises viral structural and/or accessory genes, e.g., gag, pol, env, tat, rev, vif, vpr, vpu, vpx, or nef genes or other retroviral genes.

In some embodiments, the packaging vector is an expression vector or viral vector that lacks a packaging signal and comprises a polynucleotide encoding one, two, three, four or more viral structural and/or accessory genes. Typically, the packaging vectors are included in a producer cell, and are introduced into the cell via transfection, transduction or infection. A retroviral, e.g., lentiviral, transfer vector can be introduced into a producer cell line, via transfection, transduction or infection, to generate a source cell or cell line. The packaging vectors can be introduced into human cells or cell lines by standard methods including, e.g., calcium phosphate transfection, lipofection or electroporation. In some embodiments, the packaging vectors are introduced into the cells together with a dominant selectable marker, such as neomycin, hygromycin, puromycin, blastocidin, zeocin, thymidine kinase, DHFR, Gln synthetase or ADA, followed by selection in the presence of the appropriate drug and isolation of clones. A selectable marker gene can be linked physically to genes encoding by the packaging vector, e.g., by IRES or self-cleaving viral peptides.

In some embodiments, producer cell lines include cell lines that do not contain a packaging signal, but do stably or transiently express viral structural proteins and replication enzymes (e.g., gag, pol and env) which can package viral particles. Any suitable cell line can be employed, e.g., mammalian cells, e.g., human cells. Suitable cell lines which can be used include, for example, CHO cells, BHK cells, MDCK cells, C3H 10T1/2 cells, FLY cells, Psi-2 cells, BOSC 23 cells, PA317 cells, WEHI cells, COS cells, BSC 1 cells, BSC 40 cells, BMT 10 cells, VERO cells, W138 cells, MRCS cells, A549 cells, HT1080 cells, 293 cells, 293T cells, B-50 cells, 3T3 cells, NIH3T3 cells, HepG2 cells, Saos-2 cells, Huh7 cells, HeLa cells, W163 cells, 211 cells, and 211A cells. In embodiments, the packaging cells are 293 cells, 293T cells, or A549 cells.

In some embodiments, a source cell line includes a cell line which is capable of producing recombinant retroviral particles, comprising a producer cell line and a transfer vector construct comprising a packaging signal. Methods of preparing viral stock solutions are illustrated by, e.g., Y. Soneoka et al. (1995) Nucl. Acids Res. 23:628-633, and N. R. Landau et al. (1992) J. Virol. 66:5110-5113, which are incorporated herein by reference. Infectious virus particles may be collected from the producer cells, e.g., by cell lysis, or collection of the supernatant of the cell culture. Optionally, the collected virus particles may be enriched or purified.

In some embodiments, the source cell comprises one or more plasmids coding for viral structural proteins and replication enzymes (e.g., gag, pol and env) which can package viral particles. In some embodiments, the sequences coding for at least two of the gag, pol, and env precursors are on the same plasmid. In some embodiments, the sequences coding for the gag, pol, and env precursors are on different plasmids. In some embodiments, the sequences coding for the gag, pol, and env precursors have the same expression signal, e.g., promoter. In some embodiments, the sequences coding for the gag, pol, and env precursors have a different expression signal, e.g., different promoters. In some embodiments, expression of the gag, pol, and env precursors is inducible. In some embodiments, the plasmids coding for viral structural proteins and replication enzymes are transfected at the same time or at different times. In some embodiments, the plasmids coding for viral structural proteins and replication enzymes are transfected at the same time or at a different time from the packaging vector.

In some embodiments, the source cell line comprises one or more stably integrated viral structural genes. In some embodiments expression of the stably integrated viral structural genes is inducible.

In some embodiments, expression of the viral structural genes is regulated at the transcriptional level. In some embodiments, expression of the viral structural genes is regulated at the translational level. In some embodiments, expression of the viral structural genes is regulated at the post-translational level.

In some embodiments, expression of the viral structural genes is regulated by a tetracycline (Tet)-dependent system, in which a Tet-regulated transcriptional repressor (Tet-R) binds to DNA sequences included in a promoter and represses transcription by steric hindrance (Yao et al, 1998; Jones et al, 2005). Upon addition of doxycycline (dox), Tet-R is released, allowing transcription. Multiple other suitable transcriptional regulatory promoters, transcription factors, and small molecule inducers are suitable to regulate transcription of viral structural genes.

In some embodiments, the third-generation lentivirus components, human immunodeficiency virus type 1 (HIV) Rev, Gag/Pol, and an envelope under the control of Tet-regulated promoters and coupled with antibiotic resistance cassettes are separately integrated into the source cell genome. In some embodiments the source cell only has one copy of each of Rev, Gag/Pol, and an envelope protein integrated into the genome.

In some embodiments a nucleic acid encoding the exogenous agent (e.g., a retroviral nucleic acid encoding the exogenous agent) is also integrated into the source cell genome.

In some embodiments, a retroviral nucleic acid described herein is unable to undergo reverse transcription. Such a nucleic acid, in embodiments, is able to transiently express an exogenous agent. The retrovirus or VLP, may comprise a disabled reverse transcriptase protein, or may not comprise a reverse transcriptase protein. In embodiments, the retroviral nucleic acid comprises a disabled primer binding site (PBS) and/or att site. In embodiments, one or more viral accessory genes, including rev, tat, vif, nef, vpr, vpu, vpx and S2 or functional equivalents thereof, are disabled or absent from the retroviral nucleic acid. In embodiments, one or more accessory genes selected from S2, rev and tat are disabled or absent from the retroviral nucleic acid.

2 Cell-Derived Particles

Provided herein are targeted lipid particles that comprise a naturally derived membrane. In some embodiments, the naturally derived membrane comprises membrane vesicles prepared from cells or tissues. In some embodiments, the targeted lipid particle comprises a vesicle that is obtainable from a cell. In some embodiments, the targeted lipid particle comprises a microvesicle, an exosome, a membrane enclosed body, an apoptotic body (from apoptotic cells), a particle (which may be derived from e.g. platelets), an ectosome (derivable from, e.g., neutrophiles and monocytes in serum), a prostatosome (obtainable from prostate cancer cells), or a cardiosome (derivable from cardiac cells).

In some embodiments, the source cell is an endothelial cell, a fibroblast, a blood cell (e.g., a macrophage, a neutrophil, a granulocyte, a leukocyte), a stem cell (e.g., a mesenchymal stem cell, an umbilical cord stem cell, bone marrow stem cell, a hematopoietic stem cell, an induced pluripotent stem cell e.g., an induced pluripotent stem cell derived from a subject's cells), an embryonic stem cell (e.g., a stem cell from embryonic yolk sac, placenta, umbilical cord, fetal skin, adolescent skin, blood, bone marrow, adipose tissue, erythropoietic tissue, hematopoietic tissue), a myoblast, a parenchymal cell (e.g., hepatocyte), an alveolar cell, a neuron (e.g., a retinal neuronal cell) a precursor cell (e.g., a retinal precursor cell, a myeloblast, myeloid precursor cells, a thymocyte, a meiocyte, a megakaryoblast, a promegakaryoblast, a melanoblast, a lymphoblast, a bone marrow precursor cell, a normoblast, or an angioblast), a progenitor cell (e.g., a cardiac progenitor cell, a satellite cell, a radial gial cell, a bone marrow stromal cell, a pancreatic progenitor cell, an endothelial progenitor cell, a blast cell), or an immortalized cell (e.g., HeEa, HEK293, MRC-5, WI-38, IMR 90, IMR 91, PER.C6, HT-1080, or BJ cell). In some embodiments, the source cell is other than a 293 cell, HEK cell, human endothelial cell, or a human epithelial cell, monocyte, macrophage, dendritic cell, or stem cell.

In some embodiments, the targeted lipid particle has a density of <1, 1-1.1, 1.05-1.15, 1.1-1.2, 1.15-1.25, 1.2-1.3, 1.25-1.35, or >1.35 g/ml. In some embodiments, the targeted lipid particle composition comprises less than 0.01%, 0.05%, 0.1%, 0.5%, 1%, 1.5%, 2%, 2.5%, 3%, 4%, 5%, or 10% source cells by protein mass or less than 0.01%, 0.05%, 0.1%, 0.5%, 1%, 1.5%, 2%, 2.5%, 3%, 4%, 5%, or 10% of cells having a functional nucleus.

In embodiments, the targeted lipid particle has a size, or the population of targeted lipid particles have an average size, that is less than about 0.01%, 0.05%, 0.1%, 0.5%, 1%, 2%, 3%, 4%, 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, of that of the source cell.

In some embodiments the targeted lipid particle comprises an extracellular vesicle, e.g., a cell-derived vesicle comprising a membrane that encloses an internal space and has a smaller diameter than the cell from which it is derived. In embodiments the extracellular vesicle has a diameter from 20 nm to 1000 nm. In embodiments the targeted lipid particle comprises an apoptotic body, a fragment of a cell, a vesicle derived from a cell by direct or indirect manipulation, a vesiculated organelle, and a vesicle produced by a living cell (e.g., by direct plasma membrane budding or fusion of the late endosome with the plasma membrane). In embodiments the extracellular vesicle is derived from a living or dead organism, explanted tissues or organs, or cultured cells.

In embodiments, the targeted lipid particle comprises a nanovesicle, e.g., a cell-derived small (e.g., between 20-250 nm in diameter, or 30-150 nm in diameter) vesicle comprising a membrane that encloses an internal space, and which is generated from said cell by direct or indirect manipulation. The production of nanovesicles can, in some instances, result in the destruction of the source cell. The nanovesicle may comprise a lipid or fatty acid and polypeptide.

In embodiments, the targeted lipid particle comprises an exosome. In embodiments, the exosome is a cell-derived small (e.g., between 20-300 nm in diameter, or 40-200 nm in diameter) vesicle comprising a membrane that encloses an internal space, and which is generated from said cell by direct plasma membrane budding or by fusion of the late endosome with the plasma membrane. In embodiments, production of exosomes does not result in the destruction of the source cell. In embodiments, the exosome comprises lipid or fatty acid and polypeptide. Exemplary exosomes and other membrane-enclosed bodies are also described in WO/2017/161010, WO/2016/077639, US20160168572, US20150290343, and US20070298118, each of which is incorporated by reference herein in its entirety.

In some embodiments, the targeted lipid particle is derived from a source cell with a genetic modification which results in increased expression of an immunomodulatory agent. In some embodiments, the immunosuppressive agent is on an exterior surface of the cell. In some embodiments, the immunosuppressive agent is incorporated into the exterior surface of the targeted lipid particle. In some embodiments, the targeted lipid particle comprises an immunomodulatory agent attached to the surface of the solid particle by a covalent or non-covalent bond.

c. A. Generation of Cell-Derived Particles

In some embodiments, targeted lipid particles are generated by inducing budding of an exosome, microvesicle, membrane vesicle, extracellular membrane vesicle, plasma membrane vesicle, giant plasma membrane vesicle, apoptotic body, mitoparticle, pyrenocyte, lysosome, or other membrane enclosed vesicle.

In some embodiments, targeted lipid particles are generated by inducing cell enucleation. Enucleation may be performed using assays such as genetic, chemical (e.g., using Actinomycin D, see Bayona-Bafaluyet al., “A chemical enucleation method for the transfer of mitochondrial DNA to p° cells” Nucleic Acids Res. 2003 Aug. 15; 31(16): e98), mechanical methods (e.g., squeezing or aspiration, see Lee et al., “A comparative study on the efficiency of two enucleation methods in pig somatic cell nuclear transfer: effects of the squeezing and the aspiration methods.” Anim Biotechnol. 2008; 19(2):71-9), or combinations thereof.

In some embodiments, the targeted lipid particles are generated by inducing cell fragmentation. In some embodiments, cell fragmentation can be performed using the following methods, including, but not limited to: chemical methods, mechanical methods (e.g., centrifugation (e.g., ultracentrifugation, or density centrifugation), freeze-thaw, or sonication), or combinations thereof.

In some embodiments, the targeted lipid particle is a microvesicle. In some embodiments the microvesicle has a diameter of about 100 nm to about 2000 nm. In some embodiments, a targeted lipid particle comprises a cell ghost. In some embodiments, a vesicle is a plasma membrane vesicle, e.g. a giant plasma membrane vesicle.

In some embodiments, the source cell used to make the targeted lipid particle will not be available for testing after the targeted lipid particle is made.

In some embodiments, a characteristic of a targeted lipid particle is described by comparison to a reference cell. In embodiments, the reference cell is the source cell. In embodiments, the reference cell is a HeLa, HEK293, HFF-1, MRC-5, WI-38, IMR 90, IMR 91, PER.C6, HT-1080, or BJ cell. In some embodiments, a characteristic of a population of targeted lipid particle is described by comparison to a population of reference cells, e.g., a population of source cells, or a population of HeLa, HEK293, MRC-5, WI-38, IMR 90, IMR 91, PER.C6, HT-1080, or BJ cells.

III. PHARMACEUTICAL COMPOSITIONS

The present disclosure also provides, in some aspects, a pharmaceutical composition comprising the targeted lipid particle composition described herein and pharmaceutically acceptable carrier. The pharmaceutical compositions can include any of the described targeted lipid particles.

In some embodiments, the targeted lipid particle meets a pharmaceutical or good manufacturing practices (GMP) standard. In some embodiments, the targeted lipid particle was made according to good manufacturing practices (GMP). In some embodiments, the targeted lipid particle has a pathogen level below a predetermined reference value, e.g., is substantially free of pathogens. In some embodiments, the targeted lipid particle has a contaminant level below a predetermined reference value, e.g., is substantially free of contaminants In some embodiments, the targeted lipid particle has low immunogenicity.

In some embodiments, provided herein are the use of pharmaceutical compositions of the invention or salts thereof to practice the methods of the invention. Such a pharmaceutical composition may consist of at least one compound or conjugate of the invention or a salt thereof in a form suitable for administration to a subject, or the pharmaceutical composition may comprise at least one compound or conjugate of the invention or a salt thereof, and one or more pharmaceutically acceptable carriers, one or more additional ingredients, or some combination of these. In some embodiments, the compound or conjugate of the invention may be present in the pharmaceutical composition in the form of a physiologically acceptable salt, such as in combination with a physiologically acceptable cation or anion, as is well known in the art.

In some embodiments, the pharmaceutical compositions useful for practicing the methods of the invention may be administered to deliver a dose of between 1 ng/kg/day and 100 mg/kg/day. In another embodiment, the pharmaceutical compositions useful for practicing the invention may be administered to deliver a dose of between 1 ng/kg/day and 500 mg/kg/day.

In some embodiments, the relative amounts of the active ingredient, the pharmaceutically acceptable carrier, and any additional ingredients in a pharmaceutical composition of the invention will vary, depending upon the identity, size, and condition of the subject treated and further depending upon the route by which the composition is to be administered. In some embodiments, the composition may comprise between 0.1% and 100% (w/w) active ingredient.

In some embodiments, pharmaceutical compositions that are useful in the methods of the invention may be suitably developed for oral, rectal, vaginal, parenteral, topical, pulmonary, intranasal, buccal, ophthalmic, or another route of administration. In some embodiments, a composition useful within the methods of the invention may be directly administered to the skin, vagina or any other tissue of a mammal. In some embodiments, formulations include liposomal preparations, resealed erythrocytes containing the active ingredient, and immunologically based formulations. In some embodiments, the route(s) of administration will be readily apparent to the skilled artisan and will depend upon any number of factors including the type and severity of the disease being treated, the type and age of the veterinary or human subject being treated, and the like.

In some embodiments, formulations of the pharmaceutical compositions described herein may be prepared by any method known or hereafter developed in the art of pharmacology. In some embodiments, preparatory methods include the step of bringing the active ingredient into association with a carrier or one or more other accessory ingredients, and then, if necessary or desirable, shaping or packaging the product into a desired single- or multi-dose unit.

In some embodiments, a “unit dose” is a discrete amount of the pharmaceutical composition comprising a predetermined amount of the active ingredient. In some embodiments, the amount of the active ingredient is generally equal to the dosage of the active ingredient that would be administered to a subject or a convenient fraction of such a dosage such as, for example, one-half or one-third of such a dosage. In some embodiments, the unit dosage form may be for a single daily dose or one of multiple daily doses (e.g., about 1 to 4 or more times per day). In some embodiments, when multiple daily doses are used, the unit dosage form may be the same or different for each dose.

In some embodiments, although the descriptions of pharmaceutical compositions provided herein are principally directed to pharmaceutical compositions that are suitable for ethical administration to humans, it will be understood by the skilled artisan that such compositions are generally suitable for administration to animals of all sorts. In some embodiments, modification of pharmaceutical compositions suitable for administration to humans in order to render the compositions suitable for administration to various animals is well understood, and the ordinarily skilled veterinary pharmacologist may design and perform such modification with merely ordinary, if any, experimentation. In some embodiments, subjects to which administration of the pharmaceutical compositions of the invention is contemplated include humans and other primates, mammals including commercially relevant mammals such as cattle, pigs, horses, sheep, cats, and dogs.

In some of any embodiments, the compositions of the invention are formulated using one or more pharmaceutically acceptable excipients or carriers. In one embodiment, the pharmaceutical compositions of the invention comprise a therapeutically effective amount of a compound or conjugate of the invention and a pharmaceutically acceptable carrier. In some embodiments, pharmaceutically acceptable carriers that are useful, include, but are not limited to, glycerol, water, saline, ethanol and other pharmaceutically acceptable salt solutions such as phosphates and salts of organic acids. Examples of these and other pharmaceutically acceptable carriers are described in Remington's Pharmaceutical Sciences (1991, Mack Publication Co., New Jersey).

In some embodiments, the carrier may be a solvent or dispersion medium containing, for example, water, ethanol, polyol (for example, glycerol, propylene glycol, and liquid polyethylene glycol, and the like), suitable mixtures thereof, and vegetable oils. In some embodiments, the proper fluidity may be maintained, for example, by the use of a coating such as lecithin, by the maintenance of the required particle size in the case of dispersion and by the use of surfactants. In some embodiments, prevention of the action of microorganisms may be achieved by various antibacterial and antifungal agents, for example, parabens, chlorobutanol, phenol, ascorbic acid, thimerosal, and the like. In some embodiments, it is preferable to include isotonic agents, for example, sugars, sodium chloride, or polyalcohols such as mannitol and sorbitol, in the composition. In some embodiments, prolonged absorption of the injectable compositions may be brought about by including in the composition an agent that delays absorption, for example, aluminum monostearate or gelatin. In one embodiment, the pharmaceutically acceptable carrier is not DMSO alone.

In some embodiments, formulations may be employed in admixtures with conventional excipients, i.e., pharmaceutically acceptable organic or inorganic carrier substances suitable for oral, vaginal, parenteral, nasal, intravenous, subcutaneous, enteral, or any other suitable mode of administration, known to the art. In some embodiments, the pharmaceutical preparations may be sterilized and if desired mixed with auxiliary agents, e.g., lubricants, preservatives, stabilizers, wetting agents, emulsifiers, salts for influencing osmotic pressure buffers, coloring, flavoring and/or aromatic substances and the like. In some embodiments, pharmaceutical preparations may also be combined where desired with other active agents, e.g., other analgesic agents.

In some embodiments, “additional ingredients” include, but are not limited to, one or more of the following: excipients; surface active agents; dispersing agents; inert diluents; granulating and disintegrating agents; binding agents; lubricating agents; sweetening agents; flavoring agents; coloring agents; preservatives; physiologically degradable compositions such as gelatin; aqueous vehicles and solvents; oily vehicles and solvents; suspending agents; dispersing or wetting agents; emulsifying agents, demulcents; buffers; salts; thickening agents; fillers; emulsifying agents; antioxidants; antibiotics; antifungal agents; stabilizing agents; and pharmaceutically acceptable polymeric or hydrophobic materials. In some embodiments, “additional ingredients” that may be included in the pharmaceutical compositions of the invention are known in the art and described, for example in Genaro, ed. (1985, Remington's Pharmaceutical Sciences, Mack Publishing Co., Easton, Pa.), which is incorporated herein by reference.

In some embodiments, the composition of the invention may comprise a preservative from about 0.005% to 2.0% by total weight of the composition. In some embodiments, the preservative is used to prevent spoilage in the case of exposure to contaminants in the environment. In some embodiments, examples of preservatives useful in accordance with the invention included but are not limited to those selected from the group consisting of benzyl alcohol, sorbic acid, parabens, imidurea and combinations thereof. In some embodiments, a particularly preferred preservative is a combination of about 0.5% to 2.0% benzyl alcohol and 0.05% to 0.5% sorbic acid.

In some embodiments, the composition preferably includes an anti-oxidant and a chelating agent that inhibits the degradation of the compound. In some embodiments, antioxidants for some compounds are BHT, BHA, alpha-tocopherol and ascorbic acid in the preferred range of about 0.01% to 0.3% and more preferably BHT in the range of 0.03% to 0.1% by weight by total weight of the composition. In some embodiments, the chelating agent is present in an amount of from 0.01% to 0.5% by weight by total weight of the composition. Particularly preferred chelating agents include edetate salts (e.g. disodium edetate) and citric acid in the weight range of about 0.01% to 0.20% and more preferably in the range of 0.02% to 0.10% by weight by total weight of the composition. In some embodiments, the chelating agent is useful for chelating metal ions in the composition that may be detrimental to the shelf life of the formulation. In some embodiments, other suitable and equivalent antioxidants and chelating agents may be substituted therefore as would be known to those skilled in the art.

In some embodiments, liquid suspensions may be prepared using conventional methods to achieve suspension of the active ingredient in an aqueous or oily vehicle. In some embodiments, aqueous vehicles include, for example, water, and isotonic saline. In some embodiments, oily vehicles include, for example, almond oil, oily esters, ethyl alcohol, vegetable oils such as arachis, olive, sesame, or coconut oil, fractionated vegetable oils, and mineral oils such as liquid paraffin. In some embodiments, liquid suspensions may further comprise one or more additional ingredients including, but not limited to, suspending agents, dispersing or wetting agents, emulsifying agents, demulcents, preservatives, buffers, salts, flavorings, coloring agents, and sweetening agents. In some embodiments, oily suspensions may further comprise a thickening agent. In some embodiments, suspending agents include, but are not limited to, sorbitol syrup, hydrogenated edible fats, sodium alginate, polyvinylpyrrolidone, gum tragacanth, gum acacia, and cellulose derivatives such as sodium carboxymethylcellulose, methylcellulose, hydroxypropylmethylcellulose. In some embodiments, dispersing or wetting agents include, but are not limited to, naturally-occurring phosphatides such as lecithin, condensation products of an alkylene oxide with a fatty acid, with a long chain aliphatic alcohol, with a partial ester derived from a fatty acid and a hexitol, or with a partial ester derived from a fatty acid and a hexitol anhydride (e.g., polyoxyethylene stearate, heptadecaethyleneoxycetanol, polyoxyethylene sorbitol monooleate, and polyoxyethylene sorbitan monooleate, respectively). Known emulsifying agents include, but are not limited to, lecithin, and acacia. Known preservatives include, but are not limited to, methyl, ethyl, or n-propyl-para-hydroxybenzoates, ascorbic acid, and sorbic acid. Known sweetening agents include, for example, glycerol, propylene glycol, sorbitol, sucrose, and saccharin. Known thickening agents for oily suspensions include, for example, beeswax, hard paraffin, and cetyl alcohol.

In some embodiments, liquid solutions of the active ingredient in aqueous or oily solvents may be prepared in substantially the same manner as liquid suspensions, the primary difference being that the active ingredient is dissolved, rather than suspended in the solvent. As used herein, an “oily” liquid is one which comprises a carbon-containing liquid molecule and which exhibits a less polar character than water. In some embodiments, liquid solutions of the pharmaceutical composition of the invention may comprise each of the components described with regard to liquid suspensions, it being understood that suspending agents will not necessarily aid dissolution of the active ingredient in the solvent. In some embodiments, aqueous solvents include, for example, water, and isotonic saline. In some embodiments, oily solvents include, for example, almond oil, oily esters, ethyl alcohol, vegetable oils such as arachis, olive, sesame, or coconut oil, fractionated vegetable oils, and mineral oils such as liquid paraffin.

In some embodiments, powdered and granular formulations of a pharmaceutical preparation of the invention may be prepared using known methods. In some embodiments, formulations may be administered directly to a subject, used, for example, to form tablets, to fill capsules, or to prepare an aqueous or oily suspension or solution by addition of an aqueous or oily vehicle thereto. In some of any embodiments, formulations may further comprise one or more of dispersing or wetting agent, a suspending agent, and a preservative. Additional excipients, such as fillers and sweetening, flavoring, or coloring agents, may also be included in these formulations.

In some embodiments, a pharmaceutical composition of the invention may also be prepared, packaged, or sold in the form of oil-in-water emulsion or a water-in-oil emulsion. In some embodiments, the oily phase may be a vegetable oil such as olive or arachis oil, a mineral oil such as liquid paraffin, or a combination of these. In some embodiments, compositions further comprise one or more emulsifying agents such as naturally occurring gums such as gum acacia or gum tragacanth, naturally-occurring phosphatides such as soybean or lecithin phosphatide, esters or partial esters derived from combinations of fatty acids and hexitol anhydrides such as sorbitan monooleate, and condensation products of such partial esters with ethylene oxide such as polyoxyethylene sorbitan monooleate. In some embodiments, emulsions may also contain additional ingredients including, for example, sweetening or flavoring agents.

IV. METHODS OF TREATMENT

In some embodiments, the targeted lipid particles provided herein, or pharmaceutical compositions thereof as described herein can be administered to a subject, e.g. a mammal, e.g. a human. In such embodiments, the subject may be at risk of, may have a symptom of, or may be diagnosed with or identified as having, a particular disease or condition. In one embodiment, the subject has cancer. In one embodiment, the subject has an infectious disease. In some embodiments, the targeted lipid particle contains nucleic acid sequences encoding an exogenous agent for treating the disease or condition in the subject. For example, the exogenous agent is one that targets or is specific for a protein of a neoplastic cells and the targeted lipid particle is administered to a subject for treating a tumor or cancer in the subject. In another example, the exogenous agent is an inflammatory mediator or immune molecule, such as a cytokine, and targeted lipid particle is administered to a subject for treating any condition in which it is desired to modulate (e.g. increase) the immune response, such as a cancer or infectious disease. In some embodiments, the targeted lipid particle is administered in an effective amount or dose to effect treatment of the disease, condition or disorder. Provided herein are uses of any of the provided targeted lipid particles in such methods and treatments, and in the preparation of a medicament in order to carry out such therapeutic methods. In some embodiments, the methods are carried out by administering the targeted lipid particle or compositions comprising the same, to the subject having, having had, or suspected of having the disease or condition or disorder. In some embodiments, the methods thereby treat the disease or condition or disorder in the subject. Also provided herein are uses of any of the compositions, such as pharmaceutical compositions provided herein, for the treatment of a disease, condition or disorder associated with a particular gene or protein targeted by or provided by the exogenous agent.

In some embodiments, the provided methods or uses involve administration of a pharmaceutical composition comprising oral, inhaled, transdermal or parenteral (including intravenous, intratumoral, intraperitoneal, intramuscular, intracavity, and subcutaneous) administration. In some embodiments, the targeted lipid particle may be administered alone or formulated as a pharmaceutical composition. In some embodiments, the targeted lipid particle or compositions described herein can be administered to a subject, e.g., a mammal, e.g., a human. In some of any embodiments, the subject may be at risk of, may have a symptom of, or may be diagnosed with or identified as having, a particular disease or condition (e.g., a disease or condition described herein). In some embodiments, the disease is a disease or disorder.

In some embodiments, the targeted lipid particles may be administered in the form of a unit-dose composition, such as a unit dose oral, parenteral, transdermal or inhaled composition. In some embodiments, the compositions are prepared by admixture and are adapted for oral, inhaled, transdermal or parenteral administration, and as such may be in the form of tablets, capsules, oral liquid preparations, powders, granules, lozenges, reconstitutable powders, injectable and infusable solutions or suspensions or suppositories or aerosols.

In some embodiments, the regimen of administration may affect what constitutes an effective amount. In some embodiments, the therapeutic formulations may be administered to the subject either prior to or after a diagnosis of disease. In some embodiments, several divided dosages, as well as staggered dosages may be administered daily or sequentially, or the dose may be continuously infused, or may be a bolus injection. In some embodiments, the dosages of the therapeutic formulations may be proportionally increased or decreased as indicated by the exigencies of the therapeutic or prophylactic situation.

In some embodiments, the administration of the compositions of the present invention to a subject, preferably a mammal, more preferably a human, may be carried out using known procedures, at dosages and for periods of time effective to prevent or treat disease. In some embodiments, an effective amount of the therapeutic compound necessary to achieve a therapeutic effect may vary according to factors such as the activity of the particular compound employed; the time of administration; the rate of excretion of the compound; the duration of the treatment; other drugs, compounds or materials used in combination with the compound; the state of the disease or disorder, age, sex, weight, condition, general health and prior medical history of the subject being treated, and like factors well-known in the medical arts. In some embodiments, the dosage regimens may be adjusted to provide the optimum therapeutic response. In some embodiments, several divided doses may be administered daily or the dose may be proportionally reduced as indicated by the exigencies of the therapeutic situation. In some embodiments, the effective dose range for a therapeutic compound of the invention is from about 1 and 5,000 mg/kg of body weight/per day. One of ordinary skill in the art would be able to study the relevant factors and make the determination regarding the effective amount of the therapeutic compound without undue experimentation.

In some embodiments, the compound may be administered to a subject as frequently as several times daily, or it may be administered less frequently, such as once a day, once a week, once every two weeks, once a month, or even less frequently, such as once every several months or even once a year or less. In some embodiments, the amount of compound dosed per day may be administered, in non-limiting examples, every day, every other day, every 2 days, every 3 days, every 4 days, or every 5 days. In some embodiments, with every other day administration, a 5 mg per day dose may be initiated on Monday with a first subsequent 5 mg per day dose administered on Wednesday, a second subsequent 5 mg per day dose administered on Friday, and so on. The frequency of the dose will be readily apparent to the skilled artisan and will depend upon any number of factors, such as, but not limited to, the type and severity of the disease being treated, the type and age of the animal, etc.

In some embodiments, dosage levels of the active ingredients in the pharmaceutical compositions of this invention may be varied so as to obtain an amount of the active ingredient that is effective to achieve the desired therapeutic response for a particular subject, composition, and mode of administration, without being toxic to the subject.

A medical doctor, e.g., physician or veterinarian, having ordinary skill in the art may readily determine and prescribe the effective amount of the pharmaceutical composition required. In some embodiments, the physician or veterinarian could start doses of the compounds of the invention employed in the pharmaceutical composition at levels lower than that required in order to achieve the desired therapeutic effect and gradually increase the dosage until the desired effect is achieved.

In some embodiments, it is especially advantageous to formulate the compound in dosage unit form for ease of administration and uniformity of dosage. In some embodiments, dosage unit form as used herein refers to physically discrete units suited as unitary dosages for the subjects to be treated; each unit containing a predetermined quantity of therapeutic compound calculated to produce the desired therapeutic effect in association with the required pharmaceutical vehicle. In some embodiments, the dosage unit forms of the invention are dictated by and directly dependent on (a) the unique characteristics of the therapeutic compound and the particular therapeutic effect to be achieved, and (b) the limitations inherent in the art of compounding/formulating such a therapeutic compound for the treatment of a disease in a subject.

In some embodiments, the term “container” includes any receptacle for holding the pharmaceutical composition. In some embodiments, the container is the packaging that contains the pharmaceutical composition. In other embodiments, the container is not the packaging that contains the pharmaceutical composition, i.e., the container is a receptacle, such as a box or vial that contains the packaged pharmaceutical composition or unpackaged pharmaceutical composition and the instructions for use of the pharmaceutical composition. It should be understood that the instructions for use of the pharmaceutical composition may be contained on the packaging containing the pharmaceutical composition, and as such the instructions form an increased functional relationship to the packaged product. In some embodiments, instructions may contain information pertaining to the compound's ability to perform its intended function, e.g., treating or preventing a disease in a subject, or delivering an imaging or diagnostic agent to a subject.

In some embodiments, routes of administration of any of the compositions disclosed herein include oral, nasal, rectal, parenteral, sublingual, transdermal, transmucosal (e.g., sublingual, lingual, (trans)buccal, (trans)urethral, vaginal (e.g., trans- and perivaginally), (intra)nasal, and (trans)rectal), intravesical, intrapulmonary, intraduodenal, intragastrical, intrathecal, subcutaneous, intramuscular, intradermal, intra-arterial, intravenous, intrabronchial, inhalation, and topical administration.

In some of any embodiments, suitable compositions and dosage forms include, for example, tablets, capsules, caplets, pills, gel caps, troches, dispersions, suspensions, solutions, syrups, granules, beads, transdermal patches, gels, powders, pellets, magmas, lozenges, creams, pastes, plasters, lotions, discs, suppositories, liquid sprays for nasal or oral administration, dry powder or aerosolized formulations for inhalation, compositions and formulations for intravesical administration and the like.

In some embodiments, the targeted lipid particle composition comprising an exogenous agent or cargo, may be used to deliver such exogenous agent or cargo to a cell tissue or subject. In some embodiments, delivery of a cargo by administration of a targeted lipid particle composition described herein may modify cellular protein expression levels. In certain embodiments, the administered composition directs upregulation of (via expression in the cell, delivery in the cell, or induction within the cell) of one or more cargo (e.g., a polypeptide or mRNA) that provide a functional activity which is substantially absent or reduced in the cell in which the polypeptide is delivered. In some embodiments, the missing functional activity may be enzymatic, structural, or regulatory in nature. In some embodiments, the administered composition directs up-regulation of one or more polypeptides that increases (e.g., synergistically) a functional activity which is present but substantially deficient in the cell in which the polypeptide is upregulated. In some of any embodiments, the administered composition directs downregulation of (via expression in the cell, delivery in the cell, or induction within the cell) of one or more cargo (e.g., a polypeptide, siRNA, or miRNA) that repress a functional activity which is present or upregulated in the cell in which the polypeptide, siRNA, or miRNA is delivered. In some of any embodiments, the upregulated functional activity may be enzymatic, structural, or regulatory in nature. In some embodiments, the administered composition directs down-regulation of one or more polypeptides that decreases (e.g., synergistically) a functional activity which is present or upregulated in the cell in which the polypeptide is downregulated. In some embodiments, the administered composition directs upregulation of certain functional activities and downregulation of other functional activities.

In some of any embodiments, the targeted lipid particle composition (e.g., one comprising mitochondria or DNA) mediates an effect on a target cell, and the effect lasts for at least 1, 2, 3, 4, 5, 6, or 7 days, 2, 3, or 4 weeks, or 1, 2, 3, 6, or 12 months. In some embodiments (e.g., wherein the targeted lipid particle composition comprises an exogenous protein), the effect lasts for less than 1, 2, 3, 4, 5, 6, or 7 days, 2, 3, or 4 weeks, or 1, 2, 3, 6, or 12 months.

In some of any embodiments, the targeted lipid particle composition described herein is delivered ex-vivo to a cell or tissue, e.g., a human cell or tissue. In embodiments, the composition improves function of a cell or tissue ex-vivo, e.g., improves cell viability, respiration, or other function (e.g., another function described herein).

In some embodiments, the composition is delivered to an ex vivo tissue that is in an injured state (e.g., from trauma, disease, hypoxia, ischemia or other damage).

In some embodiments, the composition is delivered to an ex-vivo transplant (e.g., a tissue explant or tissue for transplantation, e.g., a human vein, a musculoskeletal graft such as bone or tendon, cornea, skin, heart valves, nerves; or an isolated or cultured organ, e.g., an organ to be transplanted into a human, e.g., a human heart, liver, lung, kidney, pancreas, intestine, thymus, eye). In some embodiments, the composition is delivered to the tissue or organ before, during and/or after transplantation.

In some embodiments, the composition is delivered, administered or contacted with a cell, e.g., a cell preparation. In some embodiments, the cell preparation may be a cell therapy preparation (a cell preparation intended for administration to a human subject). In embodiments, the cell preparation comprises cells expressing a chimeric antigen receptor (CAR), e.g., expressing a recombinant CAR. The cells expressing the CAR may be, e.g., T cells, Natural Killer (NK) cells, cytotoxic T lymphocytes (CTL), regulatory T cells. In embodiments, the cell preparation is a neural stem cell preparation. In embodiments, the cell preparation is a mesenchymal stem cell (MSC) preparation. In embodiments, the cell preparation is a hematopoietic stem cell (HSC) preparation. In embodiments, the cell preparation is an islet cell preparation.

In some embodiments, the targeted lipid particle compositions described herein can be administered to a subject, e.g., a mammal, e.g., a human. In such embodiments, the subject may be at risk of, may have a symptom of, or may be diagnosed with or identified as having, a particular disease or condition (e.g., a disease or condition described herein).

In some embodiments, the source of targeted lipid particles are from the same subject that is administered a targeted lipid particle composition. In other embodiments, they are different. In some embodiments, the source of targeted lipid particles and recipient tissue may be autologous (from the same subject) or heterologous (from different subjects). In some embodiments, the donor tissue for targeted lipid particle compositions described herein may be a different tissue type than the recipient tissue. In some embodiments, the donor tissue may be muscular tissue and the recipient tissue may be connective tissue (e.g., adipose tissue). In other embodiments, the donor tissue and recipient tissue may be of the same or different type, but from different organ systems.

In some embodiments, the targeted lipid particle composition described herein may be administered to a subject having a cancer, an autoimmune disease, an infectious disease, a metabolic disease, a neurodegenerative disease, or a genetic disease (e.g., enzyme deficiency). In some embodiments, the subject is in need of regeneration.

In some embodiments, the targeted lipid particle is co-administered with an inhibitor of a protein that inhibits membrane fusion. For example, Suppressyn is a human protein that inhibits cell-cell fusion (Sugimoto et al., “A novel human endogenous retroviral protein inhibits cell-cell fusion” Scientific Reports 3: 1462 (DOI: 10.1038/srep01462)). In some embodiments, the targeted lipid particle particles is co-administered with an inhibitor of sypressyn, e.g., a siRNA or inhibitory antibody.

V. EXEMPLARY EMBODIMENTS

Among the provided embodiments are:

1. A targeted lipid particle, comprising:

(a) a lipid bilayer enclosing a lumen,

(b) a henipavirus F protein molecule or biologically active portion thereof; and

(c) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) single domain antibody (sdAb) variable domain, wherein the sdAb variable domain is attached to the C-terminus of the G protein or the biologically active portion thereof, wherein the F protein molecule or the biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer.

2. The targeted lipid particle of embodiment 1, wherein the single domain antibody is attached to the G protein via a linker.

3. The targeted lipid particle of embodiment 2, wherein the linker is a peptide linker.

4. A targeted lipid particle, comprising:

(a) a lipid bilayer enclosing a lumen,

(b) a henipavirus F protein molecule or biologically active portion thereof; and

(c) a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or biologically active portion thereof attached to a single domain antibody (sdAb) variable domain via a peptide linker, wherein the single domain antibody binds to a cell surface molecule of a target cell,

wherein the F protein molecule or biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer.

5. The targeted lipid particle of any of embodiments 1-4, wherein N-terminus of the F protein molecule or biologically active portion thereof is exposed on the outside of lipid bilayer.

6. The targeted lipid particle of any of embodiments 1-5, wherein the C-terminus of the G protein is exposed on the outside of the lipid bilayer.

7. The targeted lipid particle of any of embodiments 1-6, wherein the single domain antibody binds a cell surface molecule present on a target cell.

8. The targeted lipid particle of embodiment 7, wherein the cell surface molecule is a protein, glycan, lipid or low molecular weight molecule.

9. The targeted lipid particle of embodiment 7, wherein the target cell is selected from the group consisting of tumor-infiltrating lymphocytes, T cells, neoplastic or tumor cells, virus-infected cells, stem cells, central nervous system (CNS) cells, hematopoeietic stem cells (HSCs), liver cells or fully differentiated cells.

10. The targeted lipid particle of embodiment 9, wherein the target cell is selected from the group consisting of a CD3+ T cell, a CD4+ Tcell, a CD8+ T cell, a hepatocyte, a haematepoietic stem cell, a CD34+ haematepoietic stem cell, a CD105+ haematepoietic stem cell, a CD117+ haematepoietic stem cell, a CD105+ endothelial cell, a B cell, a CD20+ B cell, a CD19+ B cell, a cancer cell, a CD133+ cancer cell, an EpCAM+ cancer cell, a CD19+ cancer cell, a Her2/Neu+ cancer cell, a GluA2+ neuron, a GluA4+ neuron, a NKG2D+ natural killer cell, a SLC1A3+ astrocyte, a SLC7A10+ adipocyte, or a CD30+ lung epithelial cell.

11. The targeted lipid particle of any of the preceding embodiments, wherein the single domain antibody binds an antigen or portion thereof present on a target cell.

12. The targeted lipid particle of any of embodiments 3-11, wherein the peptide linker comprises up to 65 amino acids in length.

13. The targeted lipid particle of any of embodiments 3-11, wherein the peptide linker comprises from or from about 2 to 65 amino acids, 2 to 60 amino acids, 2 to 56 amino acids, 2 to 52 amino acids, 2 to 48 amino acids, 2 to 44 amino acids, 2 to 40 amino acids, 2 to 36 amino acids, 2 to 32 amino acids, 2 to 28 amino acids, 2 to 24 amino acids, 2 to 20 amino acids, 2 to 18 amino acids, 2 to 14 amino acids, 2 to 12 amino acids, 2 to 10 amino acids, 2 to 8 amino acids, 2 to 6 amino acids, 6 to 65 amino acids, 6 to 60 amino acids, 6 to 56 amino acids, 6 to 52 amino acids, 6 to 48 amino acids, 6 to 44 amino acids, 6 to 40 amino acids, 6 to 36 amino acids, 6 to 32 amino acids, 6 to 28 amino acids, 6 to 24 amino acids, 6 to 20 amino acids, 6 to 18 amino acids, 6 to 14 amino acids, 6 to 12 amino acids, 6 to 10 amino acids, 6 to 8 amino acids, 8 to 65 amino acids, 8 to 60 amino acids, 8 to 56 amino acids, 8 to 52 amino acids, 8 to 48 amino acids, 8 to 44 amino acids, 8 to 40 amino acids, 8 to 36 amino acids, 8 to 32 amino acids, 8 to 28 amino acids, 8 to 24 amino acids, 8 to 20 amino acids, 8 to 18 amino acids, 8 to 14 amino acids, 8 to 12 amino acids, 8 to 10 amino acids, 10 to 65 amino acids, 10 to 60 amino acids, 10 to 56 amino acids, 10 to 52 amino acids, 10 to 48 amino acids, 10 to 44 amino acids, 10 to 40 amino acids, 10 to 36 amino acids, 10 to 32 amino acids, 10 to 28 amino acids, 10 to 24 amino acids, 10 to 20 amino acids, 10 to 18 amino acids, 10 to 14 amino acids, 10 to 12 amino acids, 12 to 65 amino acids, 12 to 60 amino acids, 12 to 56 amino acids, 12 to 52 amino acids, 12 to 48 amino acids, 12 to 44 amino acids, 12 to 40 amino acids, 12 to 36 amino acids, 12 to 32 amino acids, 12 to 28 amino acids, 12 to 24 amino acids, 12 to 20 amino acids, 12 to 18 amino acids, 12 to 14 amino acids, 14 to 65 amino acids, 14 to 60 amino acids, 14 to 56 amino acids, 14 to 52 amino acids, 14 to 48 amino acids, 14 to 44 amino acids, 14 to 40 amino acids, 14 to 36 amino acids, 14 to 32 amino acids, 14 to 28 amino acids, 14 to 24 amino acids, 14 to 20 amino acids, 14 to 18 amino acids, 18 to 65 amino acids, 18 to 60 amino acids, 18 to 56 amino acids, 18 to 52 amino acids, 18 to 48 amino acids, 18 to 44 amino acids, 18 to 40 amino acids, 18 to 36 amino acids, 18 to 32 amino acids, 18 to 28 amino acids, 18 to 24 amino acids, 18 to 20 amino acids, 20 to 65 amino acids, 20 to 60 amino acids, 20 to 56 amino acids, 20 to 52 amino acids, 20 to 48 amino acids, 20 to 44 amino acids, 20 to 40 amino acids, 20 to 36 amino acids, 20 to 32 amino acids, 20 to 28 amino acids, 20 to 26 amino acids, 20 to 24 amino acids, 24 to 65 amino acids, 24 to 60 amino acids, 24 to 56 amino acids, 24 to 52 amino acids, 24 to 48 amino acids, 24 to 44 amino acids, 24 to 40 amino acids, 24 to 36 amino acids, 24 to 32 amino acids, 24 to 30 amino acids, 24 to 28 amino acids, 28 to 65 amino acids, 28 to 60 amino acids, 28 to 56 amino acids, 28 to 52 amino acids, 28 to 48 amino acids, 28 to 44 amino acids, 28 to 40 amino acids, 28 to 36 amino acids, 28 to 34 amino acids, 28 to 32 amino acids, 32 to 65 amino acids, 32 to 60 amino acids, 32 to 56 amino acids, 32 to 52 amino acids, 32 to 48 amino acids, 32 to 44 amino acids, 32 to 40 amino acids, 32 to 38 amino acids, 32 to 36 amino acids, 36 to 65 amino acids, 36 to 60 amino acids, 36 to 56 amino acids, 36 to 52 amino acids, 36 to 48 amino acids, 36 to 44 amino acids, 36 to 40 amino acids, 40 to 65 amino acids, 40 to 60 amino acids, 40 to 56 amino acids, 40 to 52 amino acids, 40 to 48 amino acids, 40 to 44 amino acids, 44 to 65 amino acids, 44 to 60 amino acids, 44 to 56 amino acids, 44 to 52 amino acids, 44 to 48 amino acids, 48 to 65 amino acids, 48 to 60 amino acids, 48 to 56 amino acids, 48 to 52 amino acids, 50 to 65 amino acids, 50 to 60 amino acids, 50 to 56 amino acids, 50 to 52 amino acids, 54 to 65 amino acids, 54 to 60 amino acids, 54 to 56 amino acids, 58 to 65 amino acids, 58 to 60 amino acids, or 60 to 65 amino acids.

14. The targeted lipid particle of any of embodiments 3-1 1, wherein peptide linker comprises a polypeptide that is 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64 or 65 amino acids in length.

15. The targeted lipid particle of any of embodiments 3-14, wherein the peptide linker is a flexible linker that comprises GS, GGS, GGGGS (SEQ ID NO:43), GGGGGS (SEQ ID NO:41) or combinations thereof.

16. The targeted lipid particle of any of embodiments 3-15, wherein the peptide linker comprises (GGS)n, wherein n is 1 to 10.

17. The targeted lipid particle of any of embodiments 3-15, wherein the peptide linker comprises (GGGGS)n (SEQ ID NO:42), wherein n is 1 to 10.

18. The targeted lipid particle of any of embodiments 3-15, wherein the peptide linker comprises (GGGGGS)n (SEQ ID NO:27), wherein n is 1 to 6.

19. The targeted lipid particle of any of embodiments 1-18, wherein the G protein or the biologically active portion thereof is a wild-type Nipah virus G (NiV-G) protein or a Hendra virus G protein.

20. The targeted lipid particle of any of embodiments 1-19, wherein the G protein or the biologically active portion thereof is a wild-type NiV-G protein or a functionally active variant or biologically active portion thereof.

21. The targeted lipid particle of embodiment 20, wherein the mutant NiV-G protein or functionally active variant or biologically active portion thereof comprises an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44.

22. The targeted lipid particle of embodiment 21, wherein the NiV-G protein is a biologically active portion that is truncated and lacks up to 40 contiguous amino acid residues at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

23. The targeted lipid particle of any of embodiments 1-18, wherein the NiV-G protein is a biologically active portion that is truncated at the N-terminus of wild-type NiV-G and has the sequence set forth in any of SEQ ID NOS: 10-15, 35-40 or 45-50 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at least at or about 84%, at least at or about 85%, at least at or about 86%, at least at or about 87%, at least at or about 88%, at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NOs: 10-15, 35-40 or 45-50.

24. The targeted lipid particle of any of embodiments 21-23, wherein the NiV-G protein has a 5 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

25. The targeted lipid particle of embodiment 24, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 10 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:10.

26. The targeted lipid particle of embodiment 24, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 35 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:35.

27. The targeted lipid particle of embodiment 24, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 45 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:45.

28. The targeted lipid particle of any of embodiments 21-23, wherein the NiV-G protein has a 10 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

29. The targeted lipid particle of embodiment 28, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 11 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:11.

30. The targeted lipid particle of embodiment 28, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 36 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:36.

31. The targeted lipid particle of embodiment 28, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 46 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:46.

32. The targeted lipid particle of any of embodiments 21-23, wherein the NiV-G protein has a 15 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

33. The targeted lipid particle of embodiment 32, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 12 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:12.

34. The targeted lipid particle of embodiment 32, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 37 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:37.

35. The targeted lipid particle of embodiment 32, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 47 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:47.

36. The targeted lipid particle of any of embodiments 21-23, wherein the NiV-G protein has a 20 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

37. The targeted lipid particle of embodiment 36, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 13 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:13.

38. The targeted lipid particle of embodiment 36, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 38 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:38.

39. The targeted lipid particle of embodiment 36, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 48 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:48.

40. The targeted lipid particle of any of embodiments 21-23, wherein the NiV-G protein has a 25 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

41. The targeted lipid particle of embodiment 40, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 14 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:14.

42. The targeted lipid particle of embodiment 40, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 39 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:39.

43. The targeted lipid particle of embodiment 40, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 49 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:49.

44. The targeted lipid particle of any of embodiments 21-23, wherein the NiV-G protein has a 30 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

45. The targeted lipid particle of embodiment 44, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 15 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:15.

46. The targeted lipid particle of embodiment 44, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 40 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:40.

47. The targeted lipid particle of embodiment 44, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 50 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:50.

48. The targeted lipid particle of any of embodiments 21-23, wherein the NiV-G protein has a 34 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO:9, SEQ ID NO:28 or SEQ ID NO:44).

49. The targeted lipid particle of embodiment 48, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 22 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:22.

50. The targeted lipid particle of embodiment 48, wherein the NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 53 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:53.

51. The targeted lipid particle any of embodiments 1-48, wherein the G-protein or the biologically active portion thereof is a mutant NiV-G protein that exhibits reduced binding to Ephrin B2 or Ephrin B3.

52. The targeted lipid particle of embodiment 51, wherein the mutant NiV-G protein comprises:

one or more amino acid substitutions corresponding to amino acid substitutions selected from the group consisting of E501A, W504A, Q530A and E533A with reference to numbering set forth in SEQ ID NO:28.

53. The targeted lipid particle of embodiment 51 or embodiment 52, wherein the mutant NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 16 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:16.

54. The targeted lipid particle of embodiment 51 or embodiment 52, wherein the mutant NiV-G protein has the amino acid sequence set forth in SEQ ID NO: 51 or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:51.

55. The targeted lipid particle of any of embodiments 1-54, wherein the F protein or the biologically active portion thereof is a wild-type Nipah virus F (NiV-F) protein or a Hendra virus F protein or is a functionally active variant or biologically active portion thereof.

56. The targeted lipid particle of any of embodiments 1-55, wherein the F protein or the biologically active portion thereof is a wild-type NiV-F protein or a functionally active variant or a biologically active portion thereof.

57. The targeted lipid particle of any of embodiments 1-56, wherein the NiV-F-protein or the functionally active variant or biologically active portion thereof comprises the amino acid sequence set forth in SEQ ID NO: 2, or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 2.

58. The targeted lipid particle of any of embodiments 1-57, wherein the NiV-F protein is a is a biologically active portion thereof that has a 20 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2).

59. The targeted lipid particle of embodiment 58, wherein the NiV-F protein has an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 5.

60. The targeted lipid particle of any of embodiments 1-57, wherein the NiV-F protein is a biologically active portion thereof that comprises:

i) a 20 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2); and

ii) a point mutation on an N-linked glycosylation site.

61. The targeted lipid particle of embodiment 60, wherein the NiV-F protein has an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 7.

62. The targeted lipid particle of any of embodiments 1-57, wherein the NiV-F protein is a biologically active portion thereof that has a 22 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2).

63. The targeted lipid particle of embodiment 62, wherein the NiV-F protein has an amino acid sequence that is encoded by a sequence of nucleotides encoding a sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 8.

64. The targeted lipid particle of embodiment 63, wherein the NiV-F protein has an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 23.

65. The targeted lipid particle of any of embodiments 1-57, wherein the F-protein or the biologically active portion thereof comprises an F1 subunit or a fusogenic portion thereof.

66. The targeted lipid particle of embodiment 65, wherein the F1 subunit is a proteolytically cleaved portion of the F0 precursor.

67. The targeted lipid particle of embodiment 66, wherein the F1 subunit comprises the sequence set forth in SEQ ID NO: 4, or an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 4.

68. The targeted lipid particle of any of embodiments 1-67, wherein the lipid bilayer is derived from a membrane of a host cell used for producing a retrovirus or retrovirus-like particle.

69. The targeted lipid particle of any of embodiments 1-60, wherein the lipid bilayer is or comprises a viral envelope.

70. The targeted lipid particle of embodiment 68, wherein the retrovirus-like particle is replication defective.

71. The targeted lipid particle of any of embodiments 1-70, wherein the targeted lipid particle comprises one or more viral components other than the F protein molecule and the G protein.

72. The targeted lipid particle of embodiment 71, wherein the one or more viral components are from a retrovirus.

73. The targeted lipid particle of embodiment 72, wherein the retrovirus is a lentivirus.

74. The targeted lipid particle of any of embodiments 71-73, wherein the one or more viral components comprise a viral packaging protein selected from one or more of Gag, Pol, Rev and Tat.

75. The targeted lipid particle of any of embodiments 71-74, wherein the one or more viral components comprises one or more of (e.g., all of) the following nucleic acid sequences: 5′ LTR (e.g., comprising U5 and lacking a functional U3 domain), Psi packaging element (Psi), Central polypurine tract (cPPT)/central termination sequence (CTS) (e.g. DNA flap), Poly A tail sequence, a posttranscriptional regulatory element (e.g. WPRE), a Rev response element (RRE), and 3′ LTR (e.g., comprising U5 and lacking a functional U3).

76. The targeted lipid particle of any of embodiments 1-75, wherein the lipid particle further comprises an exogenous agent.

77. The targeted lipid particle of embodiment 76, wherein the exogenous agent is present in the lumen.

78. The targeted lipid particle of embodiment 77, wherein the exogenous agent is a protein or a nucleic acid, optionally wherein the nucleic acid is a DNA or RNA.

79. The targeted lipid particle of any of embodiments 76-78, wherein the exogenous agent encodes a therapeutic agent or a diagnostic agent.

80. The targeted lipid particle of any of embodiments 68-79, wherein the host cell is selected from the group consisting of CHO cells, BHK cells, MDCK cells, C3H 10T1/2 cells, FLY cells, Psi-2 cells, BOSC 23 cells, PA317 cells, WEHI cells, COS cells, BSC 1 cells, BSC 40 cells, BMT 10 cells, VERO cells, W138 cells, MRCS cells, A549 cells, HT1080 cells, 293 cells, 293T cells, B-50 cells, 3T3 cells, NIH3T3 cells, HepG2 cells, Saos-2 cells, Huh7 cells, HeLa cells, W163 cells, 211 cells, and 211A cells.

81. The targeted lipid particle of any of embodiments 68-80, wherein the host cell comprises 293T cells.

82. A polynucleotide comprising a nucleic acid sequence encoding (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a single domain antibody (sdAb) variable domain, wherein the sdAb variable domain is attached to the C-terminus of the G protein or the biologically active portion thereof.

83. The polynucleotide of embodiment 82, further comprising (iii) a nucleic acid sequence encoding a henipavirus F protein molecule or a biologically active portion thereof.

84. The polynucleotide of embodiment 82 or embodiment 83, further comprising at least one promoter that is operatively linked to control expression of the nucleic acid.

85. The polynucleotide of any of embodiments 83-84, wherein the promoter is a constitutive promoter.

86. The polynucleotide of any of embodiments 83-85, wherein the promoter is an inducible promoter.

87. The polynucleotide of any of embodiments 82-86, wherein the sdAb variable domain is attached to the G protein via an encoded peptide linker.

88. The polynucleotide of any of embodiments 86-87, wherein the encoded peptide linker comprises up to 65 amino acids in length.

89. The polynucleotide of any of embodiments 86-87, wherein the encoded peptide linker comprises from or from about 2 to 65 amino acids, 2 to 60 amino acids, 2 to 56 amino acids, 2 to 52 amino acids, 2 to 48 amino acids, 2 to 44 amino acids, 2 to 40 amino acids, 2 to 36 amino acids, 2 to 32 amino acids, 2 to 28 amino acids, 2 to 24 amino acids, 2 to 20 amino acids, 2 to 18 amino acids, 2 to 14 amino acids, 2 to 12 amino acids, 2 to 10 amino acids, 2 to 8 amino acids, 2 to 6 amino acids, 6 to 65 amino acids, 6 to 60 amino acids, 6 to 56 amino acids, 6 to 52 amino acids, 6 to 48 amino acids, 6 to 44 amino acids, 6 to 40 amino acids, 6 to 36 amino acids, 6 to 32 amino acids, 6 to 28 amino acids, 6 to 24 amino acids, 6 to 20 amino acids, 6 to 18 amino acids, 6 to 14 amino acids, 6 to 12 amino acids, 6 to 10 amino acids, 6 to 8 amino acids, 8 to 65 amino acids, 8 to 60 amino acids, 8 to 56 amino acids, 8 to 52 amino acids, 8 to 48 amino acids, 8 to 44 amino acids, 8 to 40 amino acids, 8 to 36 amino acids, 8 to 32 amino acids, 8 to 28 amino acids, 8 to 24 amino acids, 8 to 20 amino acids, 8 to 18 amino acids, 8 to 14 amino acids, 8 to 12 amino acids, 8 to 10 amino acids, 10 to 65 amino acids, 10 to 60 amino acids, 10 to 56 amino acids, 10 to 52 amino acids, 10 to 48 amino acids, 10 to 44 amino acids, 10 to 40 amino acids, 10 to 36 amino acids, 10 to 32 amino acids, 10 to 28 amino acids, 10 to 24 amino acids, 10 to 20 amino acids, 10 to 18 amino acids, 10 to 14 amino acids, 10 to 12 amino acids, 12 to 65 amino acids, 12 to 60 amino acids, 12 to 56 amino acids, 12 to 52 amino acids, 12 to 48 amino acids, 12 to 44 amino acids, 12 to 40 amino acids, 12 to 36 amino acids, 12 to 32 amino acids, 12 to 28 amino acids, 12 to 24 amino acids, 12 to 20 amino acids, 12 to 18 amino acids, 12 to 14 amino acids, 14 to 65 amino acids, 14 to 60 amino acids, 14 to 56 amino acids, 14 to 52 amino acids, 14 to 48 amino acids, 14 to 44 amino acids, 14 to 40 amino acids, 14 to 36 amino acids, 14 to 32 amino acids, 14 to 28 amino acids, 14 to 24 amino acids, 14 to 20 amino acids, 14 to 18 amino acids, 18 to 65 amino acids, 18 to 60 amino acids, 18 to 56 amino acids, 18 to 52 amino acids, 18 to 48 amino acids, 18 to 44 amino acids, 18 to 40 amino acids, 18 to 36 amino acids, 18 to 32 amino acids, 18 to 28 amino acids, 18 to 24 amino acids, 18 to 20 amino acids, 20 to 65 amino acids, 20 to 60 amino acids, 20 to 56 amino acids, 20 to 52 amino acids, 20 to 48 amino acids, 20 to 44 amino acids, 20 to 40 amino acids, 20 to 36 amino acids, 20 to 32 amino acids, 20 to 28 amino acids, 20 to 26 amino acids, 20 to 24 amino acids, 24 to 65 amino acids, 24 to 60 amino acids, 24 to 56 amino acids, 24 to 52 amino acids, 24 to 48 amino acids, 24 to 44 amino acids, 24 to 40 amino acids, 24 to 36 amino acids, 24 to 32 amino acids, 24 to 30 amino acids, 24 to 28 amino acids, 28 to 65 amino acids, 28 to 60 amino acids, 28 to 56 amino acids, 28 to 52 amino acids, 28 to 48 amino acids, 28 to 44 amino acids, 28 to 40 amino acids, 28 to 36 amino acids, 28 to 34 amino acids, 28 to 32 amino acids, 32 to 65 amino acids, 32 to 60 amino acids, 32 to 56 amino acids, 32 to 52 amino acids, 32 to 48 amino acids, 32 to 44 amino acids, 32 to 40 amino acids, 32 to 38 amino acids, 32 to 36 amino acids, 36 to 65 amino acids, 36 to 60 amino acids, 36 to 56 amino acids, 36 to 52 amino acids, 36 to 48 amino acids, 36 to 44 amino acids, 36 to 40 amino acids, 40 to 65 amino acids, 40 to 60 amino acids, 40 to 56 amino acids, 40 to 52 amino acids, 40 to 48 amino acids, 40 to 44 amino acids, 44 to 65 amino acids, 44 to 60 amino acids, 44 to 56 amino acids, 44 to 52 amino acids, 44 to 48 amino acids, 48 to 65 amino acids, 48 to 60 amino acids, 48 to 56 amino acids, 48 to 52 amino acids, 50 to 65 amino acids, 50 to 60 amino acids, 50 to 56 amino acids, 50 to 52 amino acids, 54 to 65 amino acids, 54 to 60 amino acids, 54 to 56 amino acids, 58 to 65 amino acids, 58 to 60 amino acids, or 60 to 65 amino acids.

90. The polynucleotide of any of embodiments 86-87, wherein the encoded peptide linker comprises a polypeptide that is 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64 or 65 amino acids in length.

91. The polynucleotide of any of embodiments 86-87, wherein the encoded peptide linker comprises GS, GGS, GGGGS (SEQ ID NO:43), GGGGGS (SEQ ID NO:41) and combinations thereof.

92. The polynucleotide of any of embodiments 86-87, wherein the encoded peptide linker comprises (GGS)n, wherein n is 1 to 10.

93. The polynucleotide of any of embodiments 86-87, wherein the encoded peptide linker comprises (GGGGS)n (SEQ ID NO:42), wherein n is 1 to 10. 94. The polynucleotide of any of embodiments 86-87, wherein the encoded peptide linker comprises (GGGGGS)n (SEQ ID NO:27), wherein n is 1 to 4.

95. The polynucleotide of any of embodiments 86-87, wherein the nucleic acid sequence encoding the G protein is a wild-type Nipah virus G (NiV-G) protein or a Hendra virus G protein or is a variant thereof that exhibits reduced binding for the native binding partner.

96. The polynucleotide of any of embodiments 82-95, wherein the nucleic acid sequence encoding the G protein is a wild-type NiV-G protein.

97. The polynucleotide of any of embodiments 82-95, wherein the nucleic acid sequence encoding the G-protein is a mutant NiV-G protein that exhibits reduced binding to Ephrin B2 or Ephrin B3.

98. The polynucleotide of embodiment 97, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO: 44.

99. The polynucleotide of any of embodiments 82-95 and 97, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the sequence set forth in any of SEQ ID NOS: 10-15, 35-40 or 45-50 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NOs: 10-15, 35-40 or 45-50.

100. The polynucleotide of any of embodiments 97-99, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises a 5 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO: 44).

101. The polynucleotide of embodiment 100, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 10 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:10.

102. The polynucleotide of embodiment 100, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 35 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:35.

103. The polynucleotide of embodiment 100, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 45 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:45.

104. The polynucleotide of any of embodiments 97-99, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises a 10 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO: 44).

105. The polynucleotide of embodiment 104, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 11 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:11.

106. The polynucleotide of embodiment 104, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 36 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:36.

107. The polynucleotide of embodiment 104, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 46 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:46.

108. The polynucleotide of any of embodiments 97-99, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises a 15 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO: 44).

109. The polynucleotide of embodiment 108, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 12 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:12.

110. The polynucleotide of embodiment 108, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 37 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:37.

111. The polynucleotide of embodiment 108, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 47 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:47.

112. The polynucleotide of any of embodiments 97-99, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises a 20 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO: 44).

113. The polynucleotide of embodiment 112, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 13 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:13.

114. The polynucleotide of embodiment 112, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 38 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:38.

115. The polynucleotide of embodiment 112, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 48 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:48.

116. The polynucleotide of any of embodiments 97-99, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises a 25 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO: 44).

117. The polynucleotide of embodiment 116, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 14 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:14.

118. The polynucleotide of embodiment 116, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 39 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:39.

119. The polynucleotide of embodiment 116, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 49 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:49.

120. The polynucleotide of any of embodiments 97-99, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises a 30 amino acid truncation at or near the N-terminus of the wild-type NiV-G protein (SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO: 44).

121. The polynucleotide of embodiment 120, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 15 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:15.

122. The polynucleotide of embodiment 120, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 40 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:40.

123. The polynucleotide of embodiment 120, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 50 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 50.

124. The polynucleotide of any of embodiments 97-99, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises:

i) a truncation at or near the N-terminus; and

ii) point mutations selected from the group consisting of E501A, W504A, Q530A and E533A.

125. The polynucleotide of embodiment 124, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 16 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:16.

126. The polynucleotide of embodiment 124, wherein the nucleic acid sequence encoding the mutant NiV-G protein comprises the amino acid sequence set forth in SEQ ID NO: 51 or an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:51.

127. A vector, comprising the polynucleotide of any of embodiments 82-126.

128. The vector of embodiment 127, wherein the vector is a mammalian vector, viral vector or artificial chromosome, optionally wherein the artificial chromosome is a bacterial artificial chromosome (BAC).

129. A cell comprising the polynucleotide of any of embodiments 82-126 or the vector of embodiment 127 or embodiment 128.

130. A method of making a targeted lipid particle comprising a henipavirus F protein molecule or biologically active portion thereof and a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain comprising:

a) providing a cell that comprises a nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and a nucleic acid encoding a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain;

b) culturing the cell under conditions that allow for production of a targeted lipid particle, and

c) separating, enriching, or purifying the targeted lipid particle from the cell, thereby making the targeted lipid particle.

131. A method of making a targeted lipid particle comprising a henipavirus F protein molecule or biologically active portion thereof and a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain, comprising:

a) providing a cell that comprises the polynucleotide of any of embodiments 82-126 or the vector of embodiment 127 or embodiment 128;

b) providing the cell a polynucleotide encoding a henipavirus F protein molecule or biologically active portion thereof;

c) culturing the cell under conditions that allow for production of a targeted lipid particle, and

d) separating, enriching, or purifying the targeted lipid particle particle from the cell, thereby making the targeted lipid particle.

132. The method of embodiment 130 or embodiment 131, wherein the cell is a mammalian cell.

133. The method of any of embodiments 130-131, wherein the cell is a producer cell and the targeted lipid particle is a viral particle or a viral-like particle, optionally a retroviral particle or a retroviral-like particle, optionally a lentiviral particle or lentiviral-like particle.

134. A producer cell comprising (i) a viral nucleic acid(s) and (ii) nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and (iii) a nucleic acid encoding a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain, optionally wherein the viral nucleic acid(s) are lentiviral nucleic acids.

135. The producer cell of embodiment 134, wherein the viral nucleic acid(s) lacks one or more genes involved in viral replication.

136. The producer cell of embodiment 134 or embodiment 135, wherein the viral nucleic acid comprises a nucleic acid encoding a viral packaging protein selected from one or more of Gag, Pol, Rev and Tat.

137. The producer cell of any of embodiments 134-136, wherein the viral nucleic acid comprises:

one or more of (e.g., all of) the following nucleic acid sequences: 5′ LTR (e.g., comprising U5 and lacking a functional U3 domain), Psi packaging element (Psi), Central polypurine tract (cPPT)/central termination sequence (CTS) (e.g. DNA flap), Poly A tail sequence, a posttranscriptional regulatory element (e.g. WPRE), a Rev response element (RRE), and 3′ LTR (e.g., comprising U5 and lacking a functional U3);

138. The producer cell of any of embodiments 134-137, wherein the henipavirus F protein molecule or biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 2;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:2.

139. The producer cell of any of embodiments 134-137, wherein the henipavirus F protein molecule or biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 5;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:5.

140. The producer cell of any of embodiments 134-137, wherein the henipavirus F protein molecule or biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 7;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:7.

141. The producer cell of any of embodiments 134-137, wherein the henipavirus F protein molecule or biologically active portion thereof comprises:

(i) a sequence encoding by a nucleotide sequence encoding the sequence set forth in SEQ ID NO: 8;

(ii) a amino acid sequence encoded by a nucleotide sequence encoding a sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:8.

142. The producer cell of any of embodiments 134-137, wherein the henipavirus F protein molecule or biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 23;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:23.

143. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO:44;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO: 9, SEQ ID NO:28 or SEQ ID NO:44.

144. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 10;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:10.

145. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 35;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:35.

146. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 45;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:45.

147. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 11;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:11.

148. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 36;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:36.

149. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 46;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:46.

150. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 12;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:12.

151. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 37;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:37.

152. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 47;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:47.

153. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 13;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:13.

154. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 38;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:38.

155. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 48;

(ii) an amino acid sequence having at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:48.

156. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 14;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:14.

157. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 39;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:39.

158. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 49;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:49.

159. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 15;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:15.

160. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 40;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:40.

161. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 50;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at least at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:50.

162. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 16;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:16.

163. The producer cell of any of embodiments 134-142, wherein the henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof comprises:

(i) the sequence set forth in SEQ ID NO: 51;

(ii) an amino acid sequence having at least at or about 80%, at least at or about 81%, at least at or about 82%, at least at or about 83%, at or about 84%, at least at or about 85%, at least at or about 86%, or at least at or about 87%, at least at or about 88%, or at least at or about 89%, at or about 90%, at least at or about 91%, at least at or about 92%, at least at or about 93%, at least at or about 94%, at least at or about 95%, at least at or about 96%, at least at or about 97%, at least at or about 98%, or at least at or about 99% sequence identity to SEQ ID NO:51.

164. A viral vector particle or viral-like particle produced from the producer cell of any of embodiments 134-163.

165. A composition comprising a plurality of targeted lipid particles of any of embodiments 1-81 and 173-176.

166. The composition of embodiment 165 further comprising a pharmaceutically acceptable carrier.

167. The pharmaceutical composition of embodiment 165 or embodiment 166, wherein the targeted lipid particles comprise an average diameter of less than 1 μm.

168. A method of delivering an exogenous agent to a subject (e.g., a human subject), the method comprising administering to the subject the targeted lipid particle of any of embodiments 1-81 and 173-176 or the composition of any of embodiments 165-167 and 177.

169. A method of treating a disease or disorder in a subject (e.g., a human subject), the method comprising administering to the subject a targeted lipid particle of any of embodiments 1-81 and 173-176 or the composition of any of embodiments 165-167 and 177.

170. A method of fusing a mammalian cell to a targeted lipid particle, the method comprising administering to the subject a targeted lipid particle of any of embodiments 1-81 and 173-176 or the composition of any of embodiments 165-167 and 177.

171. The method of embodiment 170, wherein the fusing of the mammalian cell to the targeted lipid particle delivers an exogenous agent to a subject (e.g., a human subject).

172. The method of embodiment 170 or embodiment 171, wherein the fusing of the mammalian cell to the targeted lipid particle treats a disease or disorder in a subject (e.g., a human subject).

173. The targeted lipid particle of any of embodiments 1-81, wherein the targeted lipid particle has greater expression of the targeted envelope protein compared to a reference lipid particle that has incorporated into a similar lipid bilayer the same envelope protein but that is fused to an alternative targeting moiety, optionally wherein the alternative targeting moiety is a single chain variable fragment (scFv).

174. The targeted lipid particle of embodiment 173, wherein the expression is increased by at or greater than 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 125%, 150%, 200%, 300%, 400%, 500% or more.

175. The targeted lipid particle of embodiment 173, wherein the expression is increased by at or greater than 1.5-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold, 15-fold, 20-fold, 30-fold or more, preferably at or about or greater than 10-fold or more.

176. The targeted lipid particle of any of embodiments 1-81 and 173-175 or the viral vector particle or viral-like particle of embodiment 164, wherein the titer in target cells following transduction is at or greater than 1×10⁶ transduction units (TU)/mL, at or greater than 2×10⁶ TU/mL, at or greater than 3×10⁶ TU/mL, at or greater than 4×10⁶ TU/mL, at or greater than 5×10⁶ TU/mL, at or greater than 6×10⁶ TU/mL, at or greater than 7×10⁶ TU/mL, at or greater than 8×10⁶ TU/mL, at or greater than 9×10⁶ TU/mL, or at or greater than 1×10⁷ TU/mL.

177. The composition of any of embodiments 165-167, wherein among the population of lipid particles in the composition, greater than at or about 50%, greater than at or about 55%, greater than at or about 60%, greater than at or about 65%, greater than at or about 70%, or greater than at or about 75% are surface positive for the targeted envelope protein.

178. The targeted lipid particle of any of embodiments 1-81 and 173-176, wherein the targeted envelope protein is present on the surface of the targeted lipid particle at a density of at least about (0.001, 0.002, 0.005, 0.01, 0.02, 0.05, 0.1, 0.2 or 0.5) targeted envelope proteins/nm².

179. A composition comprising a plurality of the targeted lipid particles of any of embodiments 1-81, 173-176 and 178, wherein the targeted envelope protein is present on the surface of the targeted lipid particles at an average density of at least about (0.001, 0.002, 0.005, 0.01, 0.02, 0.05, 0.1, 0.2 or 0.5) targeted envelope proteins/nm².

180. The producer cell of any one of embodiments 134-163, wherein the producer cell has greater membrane (e.g., plasma membrane) expression of the targeted envelope protein compared to a reference producer cell that has incorporated into its membrane (e.g. plasma membrane) the same envelope protein but that is fused to an alternative targeting moiety, optionally wherein the alternative targeting moiety is a single chain variable fragment (scFv).

181. The producer cell of embodiment 180, wherein the expression is increased by at or greater than 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 125%, 150%, 200%, 300%, 400%, 500% or more.

182. The producer cell of embodiment 180, wherein the expression is increased by at or greater than 1.5-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold, 15-fold, 20-fold, 30-fold or more, preferably at or about or greater than 10-fold or more.

183. The producer cell of any one of embodiments 134-163 and 180-182, wherein the producer cell has the expression of the targeted envelope protein on a membrane (e.g., plasma membrane) of the producer cell is at least 20 proteins (e.g., at least 50, 100, 200, 500, 1000, 2000, 5000, or 10,000 proteins) per square micron.

184. The producer cell of any one of embodiments 134-163 and 180-183, wherein the targeted envelope protein comprises at least 0.1% (e.g., at least 0.2%, 0.5%, 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, or 10%) of the total membrane (e.g., plasma membrane) proteins of the producer cell (e.g., by total protein weight).

EXAMPLES

The following examples are included for illustrative purposes only and are not intended to limit the scope of the invention.

Example 1: Generation and Characterization of Producer Cells Containing Targeted Binders

This Example describes generation and assessment of NiVG targeted binding sequences in which NiVG was linked to scFv or VHH binding modalities.

A. Binding Modalities Directed to CD4.

Exemplary retargeted NivG fusogen constructs were generated containing an scFv or VHH binding modality against human cellular receptor CD4. For each binding modality, four different sequences that contained a unique CDR3 were assessed. Each exemplary binder sequence was codon optimized and cloned into an expression vector as a fusion with a sequence encoding NiVG (GcΔ34; Bender et al. 2016 PLoS Pathol 12(6):e1005641). The resulting vectors encoded a NivG targeting domain containing NiVG (SEQ ID NO:16) a flexible linker and the binding domain, followed by a 6xHis-tag for detection (NivG-linker-scFv-6xHis).

After subcloning, 5 μg of each exemplary construct was transfected into HEK 293 cells using a transfection reagent. A pcDNA3.1 plasmid (empty vector) and the expression vector without the binder domain (NiVG-linker-NoBinder) were used as negative controls.

At 48 hours post-transfection, cells were harvested and 100,000 cells were incubated for 1 hour at 4° C. with either 50 nM or 300 nM of soluble human CD4 protein with a human Fc tag (hCD4-Fc). After incubation, cells were washed and co-stained with an anti-His antibody conjugated to Alexa-647 to detect surface expression of NivG-binders and an anti-human Fc antibody conjugated to Alexa-488 to detect binding to soluble hCD4-Fc protein.

Cells were analyzed by flow cytometry, and gates for His (surface expression) and Fc (CD4-protein binding) were set based on the negative control empty vector (pcDNA3.1). Evaluation of median fluorescence intensity (MFI) of cells transfected with constructs containing VHH binding modalities demonstrated higher surface expression as quantified by % of His+ cells (FIG. 1A) and higher binding to soluble hCD4-Fc protein as quantified by % Fc+ cell (FIG. 1B), than cells transfected with constructs containing scFv binding modalities.

B. Binding Modalities Directed to Multiple Cellular Receptors

Exemplary constructs were generated containing scFv and VHH binding modalities generally as described above, but containing unique sequences directed against other cellular receptors hCD8, CD4, ASGR2, TM4SF5, LDLR or ASGR1. Multiple sequences, each containing a unique CDR3, were assessed for each binding modality containing distinct cellular receptors. After subcloning into the NivG-linker-6xHis expression vector as described above, 5 μg of each exemplary construct was transfected into about HEK 293 cells. The pcDNA3.1 plasmid (empty vector) and the expression vector without the binding domain (NiVG-linker-NoBinder) were used as negative controls.

At 48 hours post-transfection, cells were harvested and 100,000 cells were washed and stained with an anti-His antibody conjugated to Alexa-647 to detect surface expression of NivG-binders. Cells were analyzed by flow cytometry, and gates for His (surface expression) were set based on the negative control empty vector (pcDNA3.1). Median fluorescence intensity (MFI) was normalized to that of the NivG-NoBinder control set to 100. Cells transfected with constructs containing VHH binding modalities, compared to the scFv binding modalities, demonstrated higher surface expression of targeted binding sequences on 293 cells as quantified by % of His+ cells (FIG. 1C).

Example 2: Generation and Characterization of Lentiviruses Pseudotyped with Targeted Binders

This Example describes generation of lentiviruses pseudotyped with NivG retargeted fusogens and assessment of transduction of primary human T cells.

A. Generation of NivG Pseudotyped Lentiviruses.

293 cells were plated at 5.4×10⁶ into 10 cm dishes and allowed to rest for 24 hours. At 24 hours after plating, cells were transfected using polyethylenimine (PEI) with the following plasmids: NivG pseudotyped vector containing hCD4 targeted binding sequences linked to scFv or VHH binding modalities (NivG-linker-hCD4-binding modality), vector containing a nucleotide sequence encoding the NivF sequence NivFde122 (SEQ ID NO:8; or SEQ ID NO:23 without a signal sequence; Bender et al. 2016 PLoS), a packaging plasmid containing an empty backbone, an HIV-1 pol, HIV-1 gag, HIV-1 Rev, HIV-1 Tat, an AmpR promoter and an SV40 promoter and a lentiviral reporter plasmid encoding an enhanced green fluorescent protein (eGFP) under the control of a SFFV promoter pLenti-SFFV-eGFP. Positive control cells were generated using the plasmids described above along with 4 μg of VSV-G.

B. NivG Pseudotyped Lentiviral Transduction Efficiency of Primary Human T Cells.

PanT cells from peripheral blood (StemCellTech, Vancouver, Canada) that were negatively selected to enrich for T cells were thawed and activated with anti CD3/anti-CD28 for 2 days. Concentrated lentiviruses generated generally as described above were serially diluted 6-fold starting at 0.05 dilution with a total of 4 points in the dilution series. Lentiviruses were added to 100,000 PanT cells and transduced by spinfection for 90 minutes at 1000 g at 25C. Transduced PanT cells were split on days 2 and 5 post-transduction, and on day 7 post-transduction, cells were harvested and stained with an Alexa-647 conjugated anti-human CD4 antibody. Cells were analyzed by flow cytometry, and titer was determined by % of CD4-positive cells that were GFP+. Cells transfected with constructs containing VHH binding modalities demonstrated a 10-fold increased titer over constructs containing scFv binding modalities on primary human T cells (FIG. 2).

Example 3. In Vivo Delivery of Lentiviruses Pseudotyped with CD8 Targeted Binders

This Example describes generation of lentiviruses pseudotyped with a CD8 NivG retargeted fusogen and in vivo assessment of transduction of primary human T cells.

CD8 retargeted NivG fusogens were generated essentially as described in Example 2. The retargeted NivG pseudotyped fusogen contained a NivG targeting domain containing NiVG (SEQ ID NO:16) a flexible linker and an exemplary CD8 binding domain, either a VHH or scFv binding modality.

T cells from human peripheral blood mononuclear cells (PBMCs) were activated with anti CD3/anti-CD28 for 3 days. After 3 days of incubation, 1×10⁷ cells were injected intraperitoneally into NOD-scid-IL2rγ^(null) mice. One day post-injection, mice received 1×10⁷ transducing units (TU) of CD8 NivG pseudotyped lentiviruses generated as described above, or no lenti-viral vector (LVV) control, through intraperitoneal injection. On day 7 post-CD8 NivG psedudotyped lentivirus injection, peritoneal cells were harvested and analyzed by flow cytometry, and titer was determined by % of CD8 positive or negative cells that were GFP+. The CD8 retargeted pseudotyped lentiviruses demonstrated significant in vivo transduction of CD8+ T cells (FIG. 3A) and minimal transduction of CD8− T cells (FIG. 3B). These results indicate that CD8 targeted pseudotyped lentiviral-mediated delivery permits specific delivery of a transgene to the intended cell type (e.g. CD8+ T cells).

Example 4. In Vitro Assessment of Chimeric Antigen Receptor (Car) Containing Pseudotyped Lentiviruses with CD8 Targeted Binders

This Example describes the in vitro tumor killing activity of lentivirus pseudotyped with a CD8 retargeted fusogen and expressing a CD19-directed chimeric antigen receptor (CD19CAR). The lentiviruses were generated substantially as described in Example 3, except that a plasmid encoding either the eGFP or the CD19CAR were transfected into the 293 producer cells. The CD19CAR contained an anti-scFv directed against CD19 and an intracellular signaling domain containing intracellular components of 4-1BB and CD3-zeta.

Human peripheral blood mononuclear cells (PBMCs) were activated with anti CD3/anti-CD28reagent and were transduced with CD8 retargeted NivG lentiviruses expressing CD19+CAR or GFP at various concentration ranges (10-10,000 transducing units/well). RFP+Nalm6 leukemia cells were added to cultures on day 3, and elimination of Nalm6 cells was evaluated at 18 hours by flow cytometry.

As shown in FIG. 4A, CD19+CAR expression was detected specifically in CD8+ cells with both CD8 retargeted fusogens at 4 days after transduction. Transduced CD8+ T cells expressing the CD19CAR also mediated a potent and lentivirus dose-dependent increase in killing of CD19+ Nalm6 leukemia cells, while in contrast, cells transduced to express GFP did not exhibit target cell killing (FIG. 4B).

These results demonstrate that CD8-retargeted pseudotyped lentiviruses with a transgene encoding a CD19CAR deliver CD19CAR to human CD8+ T cells to mediate a specific transduction of CD8+ T cells in a complex mixture of PBMCs and showed a dose-dependent anti-tumor response by killing of leukemic cells in vitro.

The present invention is not intended to be limited in scope to the particular disclosed embodiments, which are provided, for example, to illustrate various aspects of the invention. Various modifications to the compositions and methods described will become apparent from the description and teachings herein. Such variations may be practiced without departing from the true scope and spirit of the disclosure and are intended to fall within the scope of the present disclosure.

SEQUENCES # SEQUENCE ANNOTATION 1 MVVILDKRCY CNLLILILMI SECSVGILHY EKLSKIGLVK Nipah virus GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ CTGSVMENYK NiV-F with TRLNGILTPI KGALEIYKNN THDLVGDVRL AGVIMAGVAI signal sequence GIATAAQITA GVALYEAMKN ADNINKLKSS IESTNEAVVK (aa 1-546) LQETAEKTVY VLTALQDYIN TNLVPTIDKI SCKQTELSLD Uniprot Q9IH63 LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE TLLRTLGYAT EDFDDLLESD SITGQIIYVD LSSYYIIVRV YFPILTEIQQ AYIQELLPVS FNNDNSEWIS IVPNFILVRN TLISNIEIGF CLITKRSVIC NQDYATPMTN NMRECLTGST EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNTYSRLED RRVRPTSSGD LYYIGT 2 ILHY EKLSKIGLVK GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ Nipah virus CTGSVMENYK TRLNGILTPI KGALEIYKNN THDLVGDVRL NiV-F F0 (aa 27- AGVIMAGVAI GIATAAQITA GVALYEAMKN ADNINKLKSS 546) IESTNEAVVK LQETAEKTVY VLTALQDYIN TNLVPTIDKI SCKQTELSLD LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE TLLRTLGYAT EDFDDLLESD SITGQIIYVD LSSYYIIVRV YFPILTEIQQ AYIQELLPVS FNNDNSEWIS IVPNFILVRN TLISNIEIGF CLITKRSVIC NQDYATPMTN NMRECLTGST EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNTYSRLED RRVRPTSSGD LYYIGT 3 ILHYEKLSKIGLVKGVTRKYKIKSNPLIKDIVIKMIPNVSNMSQCTGSVME Nipah virus NYKTRLNGILTPIKGALEIYKNNTHDLVGDVR NiV-F F2 (aa 27- 109) 4 LAGVIMAGVAIGIATAAQITAGVALYEAMKNADNINKLKSSIESTNEAVVK Nipah virus NiV LQETAEKTVYVLTALQDYINTNLVPTIDKISCKQTELSLDLALSKYLSDLL F F1 (aa 110- FVFGPNLQDPVSNSMTIQAISQAFGGNYETLLRTLGYATEDFDDLLESDSI 546) TGQIIYVDLSSYYIIVRVYFPILTEIQQAYIQELLPVSFNNDNSEWISIVP NFILVRNTLISNIEIGFCLITKRSVICNQDYATPMTNNMRECLTGSTEKCP RELVVSSHVPRFALSNGVLFANCISVTCQCQTTGRAISQSGEQTLLMIDNT TCPTAVLGNVIISLGKYLGSVNYNSEGIAIGPPVFTDKVDISSQISSMNQS LQQSKDYIKEAQRLLDTVNPSLISMLSMIILYVLSIASLCIGLITFISFII VEKKRNTYSRLEDRRVRPTSSGDLYYIGT 5 ILHY EKLSKIGLVK GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ Nipah virus CTGSVMENYK TRLNGILTPI KGALEIYKNN THDLVGDVRL NiV-F F0 T234 AGVIMAGVAI GIATAAQITA GVALYEAMKN ADNINKLKSS truncation (aa IESTNEAVVK LQETAEKTVY VLTALQDYIN TNLVPTIDKI 525-544) SCKQTELSLD LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE TLLRTLGYAT EDFDDLLESD SITGQIIYVD LSSYYIIVRV YFPILTEIQQ AYIQELLPVS FNNDNSEWIS IVPNFILVRN TLISNIEIGF CLITKRSVIC NQDYATPMTN NMRECLTGST EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNTGT 6 LAGVIMAGVAIGIATAAQITAGVALYEAMKNADNINKLKSSIESTNEAVVK Nipah virus NiV LQETAEKTVYVLTALQDYINTNLVPTIDKISCKQTELSLDLALSKYLSDLL F F1 (aa 110- FVFGPNLQDPVSNSMTIQAISQAFGGNYETLLRTLGYATEDFDDLLESDSI 546) truncation TGQIIYVDLSSYYIIVRVYFPILTEIQQAYIQELLPVSFNNDNSEWISIVP (aa 525-544) NFILVRNTLISNIEIGFCLITKRSVICNQDYATPMTNNMRECLTGSTEKCP RELVVSSHVPRFALSNGVLFANCISVTCQCQTTGRAISQSGEQTLLMIDNT TCPTAVLGNVIISLGKYLGSVNYNSEGIAIGPPVFTDKVDISSQISSMNQS LQQSKDYIKEAQRLLDTVNPSLISMLSMIILYVLSIASLCIGLITFISFII VEKKRNTGT 7 ILHY EKLSKIGLVK GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ Nipah virus CTGSVMENYK TRLNGILTPI KGALEIYKNQ THDLVGDVRL NiV-F F0 T234 AGVIMAGVAI GIATAAQITA GVALYEAMKN ADNINKLKSS truncation (aa IESTNEAVVK LQETAEKTVY VLTALQDYIN TNLVPTIDKI 525-544) AND SCKQTELSLD LALSKYLSDL LFVFGPNLQD PVSNSMTIQA mutation on N- ISQAFGGNYE TLLRTLGYAT EDFDDLLESD SITGQIIYVD linked LSSYYIIVRV YFPILTEIQQ AYIQELLPVS FNNDNSEWIS glycosylation IVPNFILVRN TLISNIEIGF CLITKRSVIC NQDYATPMTN site NMRECLTGST EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNTGT 8 MVVILDKRCY CNLLILILMI SECSVGILHY EKLSKIGLVK Truncated NiV GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ CTGSVMENYK fusion TRLNGILTPI KGALEIYKNN THDLVGDVRL AGVIMAGVAI glycoprotein GIATAAQITA GVALYEAMKN ADNINKLKSS IESTNEAVVK (FcDelta22) at LQETAEKTVY VLTALQDYIN TNLVPTIDKI SCKQTELSLD cytoplasmic tail LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE (with signal TLLRTLGYAT EDFDDLLESD SITGQIIYVD LSSYYIIVRV sequence) YFPILTEIQQ AYIQELLPVS FNNDNSEWIS IVPNFILVRN TLISNIEIGF CLITKRSVIC NQDYATPMTN NMRECLTGST EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNT 9 MGPAENKKVR FENTTSDKGK IPSKVIKSYY GTMDIKKINE NiVG protein GLLDSKILSA FNTVIALLGS IVIIVMNIMI IQNYTRSTDN attachment QAVIKDALQG IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT glycoprotein IPANIGLLGS KISQSTASIN ENVNEKCKFT LPPLKIHECN (602 aa) ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 10 MGKVR FENTTSDKGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA NiVG protein FNTVIALLGS IVIIVMNIMI IQNYTRSTDN QAVIKDALQG attachment IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT IPANIGLLGS glycoprotein KISQSTASIN ENVNEKCKFT LPPLKIHECN ISCPNPLPFR Truncated Δ5 EYRPQTEGVS NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 11 MGNTTSDKGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA NiVG protein FNTVIALLGS IVIIVMNIMI IQNYTRSTDN QAVIKDALQG attachment IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT IPANIGLLGS glycoprotein KISQSTASIN ENVNEKCKFT LPPLKIHECN ISCPNPLPFR Truncated Δ10 EYRPQTEGVS NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 12 MGKGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA FNTVIALLGS NiVG protein IVIIVMNIMI IQNYTRSTDN QAVIKDALQG IQQQIKGLAD attachment KIGTEIGPKV SLIDTSSTIT IPANIGLLGS KISQSTASIN glycoprotein ENVNEKCKFT LPPLKIHECN ISCPNPLPFR EYRPQTEGVS Truncated Δ15 NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 13 MGSKVIKSYY GTMDIKKINE GLLDSKILSA FNTVIALLGS NiVG protein IVIIVMNIMI IQNYTRSTDN QAVIKDALQG IQQQIKGLAD attachment KIGTEIGPKV SLIDTSSTIT IPANIGLLGS KISQSTASIN glycoprotein ENVNEKCKFT LPPLKIHECN ISCPNPLPFR EYRPQTEGVS Truncated Δ20 NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 14 MGSYY GTMDIKKINE GLLDSKILSA FNTVIALLGS IVIIVMNIMI NiVG protein IQNYTRSTDN QAVIKDALQG IQQQIKGLAD KIGTEIGPKV attachment SLIDTSSTIT IPANIGLLGS KISQSTASIN ENVNEKCKFT glycoprotein LPPLKIHECN ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC Truncated Δ25 LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 15 MGTMDIKKINE GLLDSKILSA FNTVIALLGS IVIIVMNIMI NiVG protein IQNYTRSTDN QAVIKDALQG IQQQIKGLAD KIGTEIGPKV attachment SLIDTSSTIT IPANIGLLGS KISQSTASIN ENVNEKCKFT glycoprotein LPPLKIHECN ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC Truncated Δ30 LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 16 MKKINEGLLDSKILSA FNTVIALLGS IVIIVMNIMI IQNYTRSTDN NiVG protein QAVIKDALQG IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT attachment IPANIGLLGS KISQSTASIN ENVNEKCKFT LPPLKIHECN glycoprotein ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC LQKTSNQILK Truncated and PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS mutated CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV (E501 A, YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL W504A, Q530A, AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG E533A) NiV G DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM protein (Gc Δ GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG 34) SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PAICAEGVYN DAFLIDRINW ISAGVFLDSN ATAANPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 17 MATQEVRLKC LLCGIIVLVL SLEGLGILHY EKLSKIGLVK Hendra virus F GITRKYKIKS protein NPLTKDIVIK MIPNVSNVSK CTGTVMENYK SRLTGILSPI Uniprot O89342 KGAIELYNNN (with signal THDLVGDVKL AGVVMAGIAI GIATAAQITA GVALYEAMKN sequence) ADNINKLKSS IESTNEAVVK LQETAEKTVY VLTALQDYIN TNLVPTIDQI SCKQTELALD LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE TLLRTLGYAT EDFDDLLESD SIAGQIVYVD LSSYYIIVRV YFPILTEIQQ AYVQELLPVS FNNDNSEWIS IVPNFVLIRN TLISNIEVKY CLITKKSVIC NQDYATPMTA SVRECLTGST DKCPRELVVS SHVPRFALSG GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCTTV VLGNIIISLG KYLGSINYNS ESIAVGPPVY TDKVDISSQI SSMNQSLQQS KDYIKEAQKI LDTVNPSLIS MLSMIILYVL SIAALCIGLI TFISFVIVEK KRGNYSRLDD RQVRPVSNGD LYYIGT 18 MMADSKLVSL NNNLSGKIKD QGKVIKNYYG TMDIKKINDG Hendra virus G LLDSKILGAF protein Uniprot NTVIALLGSI IIIVMNIMII QNYTRTTDNQ ALIKESLQSV O89343 QQQIKALTDK IGTEIGPKVS LIDTSSTITI PANIGLLGSK ISQSTSSINE NVNDKCKFTL PPLKIHECNI SCPNPLPFRE YRPISQGVSD LVGLPNQICL QKTTSTILKP RLISYTLPIN TREGVCITDP LLAVDNGFFA YSHLEKIGSC TRGIAKQRII GVGEVLDRGD KVPSMFMTNV WTPPNPSTIH HCSSTYHEDF YYTLCAVSHV GDPILNSTSW TESLSLIRLA VRPKSDSGDY NQKYIAITKV ERGKYDKVMP YGPSGIKQGD TLYFPAVGFL PRTEFQYNDS NCPIIHCKYS KAENCRLSMG VNSKSHYILR SGLLKYNLSL GGDIILQFIE IADNRLTIGS PSKIYNSLGQ PVFYQASYSW DTMIKLGDVD TVDPLRVQWR NNSVISRPGQ SQCPRFNVCP EVCWEGTYND AFLIDRLNWV SAGVYLNSNQ TAENPVFAVF KDNEILYQVP LAEDDTNAQK TITDCFLLEN VIWCISLVEI YDTGDSVIRP KLFAVKIPAQ CSES 19 MVVILDKRCY CNLLILILMI SECSVGILHY EKLSKIGLVK Nipah virus GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ CTGSVMENYK NiV-F F0 T234 TRLNGILTPI KGALEIYKNN THDLVGDVRL AGVIMAGVAI truncation (aa GIATAAQITA GVALYEAMKN ADNINKLKSS IESTNEAVVK 525-544)(with LQETAEKTVY VLTALQDYIN TNLVPTIDKI SCKQTELSLD signal sequence) LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE TLLRTLGYAT EDFDDLLESD SITGQIIYVD LSSYYIIVRV YFPILTEIQQ AYIQELLPVS FNNDNSEWIS IVPNFILVRN TLISNIEIGF CLITKRSVIC NQDYATPMTN NMRECLTGST EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNTGT 20 MVVILDKRCY CNLLILILMI SECSVGILHY EKLSKIGLVK Nipah virus GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ CTGSVMENYK NiV-F F0 T234 TRLNGILTPI KGALEIYKNQ THDLVGDVRL AGVIMAGVAI truncation (aa GIATAAQITA GVALYEAMKN ADNINKLKSS IESTNEAVVK 525-544) AND LQETAEKTVY VLTALQDYIN TNLVPTIDKI SCKQTELSLD mutation on N- LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE linked TLLRTLGYAT EDFDDLLESD SITGQIIYVD LSSYYIIVRV glycosylation YFPILTEIQQ AYIQELLPVS FNNDNSEWIS IVPNFILVRN site (with signal TLISNIEIGF CLITKRSVIC NQDYATPMTN NMRECLTGST sequence) EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNTGT 21 MVVILDKRCY CNLLILILMI SECSVGILHY EKLSKIGLVK Truncated NiV GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ CTGSVMENYK fusion TRLNGILTPI KGALEIYKNN THDLVGDVRL AGVIMAGVAI glycoprotein GIATAAQITA GVALYEAMKN ADNINKLKSS IESTNEAVVK (FcDelta22) at LQETAEKTVY VLTALQDYIN TNLVPTIDKI SCKQTELSLD cytoplasmic tail LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE (with signal TLLRTLGYAT EDFDDLLESD SITGQIIYVD LSSYYIIVRV sequence) YFPILTEIQQ AYIQELLPVS FNNDNSEWIS IVPNFILVRN TLISNIEIGF CLITKRSVIC NQDYATPMTN NMRECLTGST EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNT 22 MKKINEGLLDSKILSA FNTVIALLGS IVIIVMNIMI IQNYTRSTDN NiVG protein QAVIKDALQG IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT attachment IPANIGLLGS KISQSTASIN ENVNEKCKFT LPPLKIHECN glycoprotein ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC LQKTSNQILK Truncated (Gc Δ PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS 34) CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 23 ILHY EKLSKIGLVK GVTRKYKIKS NPLTKDIVIK MIPNVSNMSQ Truncated CTGSVMENYK TRLNGILTPI KGALEIYKNN THDLVGDVRL mature NiV AGVIMAGVAI GIATAAQITA GVALYEAMKN ADNINKLKSS fusion IESTNEAVVK LQETAEKTVY VLTALQDYIN TNLVPTIDKI glycoprotein SCKQTELSLD LALSKYLSDL LFVFGPNLQD PVSNSMTIQA (FcDelta22) at ISQAFGGNYE TLLRTLGYAT EDFDDLLESD SITGQIIYVD cytoplasmic tail LSSYYIIVRV YFPILTEIQQ AYIQELLPVS FNNDNSEWIS IVPNFILVRN TLISNIEIGF CLITKRSVIC NQDYATPMTN NMRECLTGST EKCPRELVVS SHVPRFALSN GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCPTA VLGNVIISLG KYLGSVNYNS EGIAIGPPVF TDKVDISSQI SSMNQSLQQS KDYIKEAQRL LDTVNPSLIS MLSMIILYVL SIASLCIGLI TFISFIIVEK KRNT 24 MSNKRTTVLIIISYTLFYLNNAAIVGFDFDKLNKIGVVQGRVLNYKIKGDP gb: JQ001776: 61 MTKDLVLKFIPNIVNITECVREPLSRYNETVRRLLLPIHNMLGLYLNNTNA 29- KMTGLMIAGVIMGGIAIGIATAAQITAGFALYEAKKNTENIQKLTDSIMKT 8166|Organism:  QDSIDKLTDSVGTSILILNKLQTYINNQLVPNLELLSCRQNKIEFDLMLTK Cedar YLVDLMTVIGPNINNPVNKDMTIQSLSLLFDGNYDIMMSELGYTPQDFLDL virus|Strain IESKSITGQIIYVDMENLYVVIRTYLPTLIEVPDAQIYEFNKITMSSNGGE Name: CG1a|Prot YLSTIPNFILIRGNYMSNIDVATCYMTKASVICNQDYSLPMSQNLRSCYQG ein Name: fusion ETEYCPVEAVIASHSPRFALTNGVIFANCINTICRCQDNGKTITQNINQFV glycoprotein|Gen SMIDNSTCNDVMVDKFTIKVGKYMGRKDINNINIQIGPQIIIDKVDLSNEI e Symbol: F NKMNQSLKDSIFYLREAKRILDSVNISLISPSVQLFLIIISVLSFIILLII (with signal IVYLYCKSKHSYKYNKFIDDPDYYNDYKRERINGKASKSNNIYYVGD sequence) 25 MALNKNMFSSLFLGYLLVYATTVQSSIHYDSLSKVGVIKGLTYNYKIKGSP gb: NC_025352: 5 STKLMVVKLIPNIDSVKNCTQKQYDEYKNLVRKALEPVKMAIDTMLNNVKS 950- GNNKYRFAGAIMAGVALGVATAATVTAGIALHRSNENAQAIANMKSAIQNT 8712|Organism:  NEAVKQLQLANKQTLAVIDTIRGEINNNIIPVINQLSCDTIGLSVGIRLTQ Mojiang YYSEIITAFGPALQNPVNTRITIQAISSVFNGNFDELLKIMGYTSGDLYEI virus|Strain LHSELIRGNIIDVDVDAGYIALEIEFPNLTLVPNAVVQELMPISYNIDGDE Name: Tongguan WVTLVPRFVLTRTTLLSNIDTSRCTITDSSVICDNDYALPMSHELIGCLQG 1|Protein DISKCAREKVVSSYVPKFALSDGLVYANCLNTICRCMDTDTPISQSLGATV Name: fusion SLLDNKRCSVYQVGDVLISVGSYLGDGEYNADNVELGPPIVIDKIDIGNQL protein|lGene AGINQTLQEAEDYIEKSEEFLKGVNPSIITLGSMVVLYIFMILIAIVSVIA Symbol: F (with LVLSIKLTVKGNVVRQQFTYTQHVPSMENINYVSH signal sequence) 26 MKKKTDNPTISKRGHNHSRGIKSRALLRETDNYSNGLIVENLVRNCHHPSK gb: NC_025256: 6 NNLNYTKTQKRDSTIPYRVEERKGHYPKIKHLIDKSYKHIKRGKRRNGHNG 865- NIITIILLLILILKTQMSEGAIHYETLSKIGLIKGITREYKVKGTPSSKDI 8853|Organism:  VIKLIPNVTGLNKCTNISMENYKEQLDKILIPINNIIELYANSTKSAPGNA Bat RFAGVIIAGVALGVAAAAQITAGIALHEARQNAERINLLKDSISATNNAVA Paramyxovirus ELQEATGGIVNVITGMQDYINTNLVPQIDKLQCSQIKTALDISLSQYYSEI Eid_hel/GH- LTVFGPNLQNPVTTSMSIQAISQSFGGNIDLLLNLLGYTANDLLDLLESKS M74a/GHA/200 ITGQITYINLEHYFMVIRVYYPIMTTISNAYVQELIKISFNVDGSEWVSLV 9|Strain PSYILIRNSYLSNIDISECLITKNSVICRHDFAMPMSYTLKECLTGDTEKC Name: BatPV/Ei PREAVVTSYVPRFAISGGVIYANCLSTTCQCYQTGKVIAQDGSQTLMMIDN d_hel/GH- QTCSIVRIEEILISTGKYLGSQEYNTMHVSVGNPVFTDKLDITSQISNINQ M74a/GHA/200 SIEQSKFYLDKSKAILDKINLNLIGSVPISILFIIAILSLILSIITFVIVM 9|Protein IIVRRYNKYTPLINSDPSSRRSTIQDVYIIPNPGEHSIRSAARSIDRDRD Name: fusion protein|Gene Symbol: F (with signal sequence) 27 (GGGGGS)n wherein n is 1 to 6 Peptide Linker 28 MPAENKKVRFENTTSDKGKIPSKVIKSYYGTMDIKKINEGLLDSKILSAFN gb: AF212302|Or TVIALLGSIVIIVMNIMIIQNYTRSTDNQAVIKDALQGIQQQIKGLADKIG ganism: Nipah TEIGPKVSLIDTSSTITIPANIGLLGSKISQSTASINENVNEKCKFTLPPL virus|Strain KIHECNISCPNPLPFREYRPQTEGVSNLVGLPNNICLQKTSNQILKPKLIS Name: UNKNO YTLPVVGQSGTCITDPLLAMDEGYFAYSHLERIGSCSRGVSKQRIIGVGEV WN- LDRGDEVPSLFMTNVWTPPNPNTVYHCSAVYNNEFYYVLCAVSTVGDPILN AF212302|Protei STYWSGSLMMTRLAVKPKSNGGGYNQHQLALRSIEKGRYDKVMPYGPSGIK n QGDTLYFPAVGFLVRTEFKYNDSNCPITKCQYSKPENCRLSMGIRPNSHYI Name: attachmen LRSGLLKYNLSDGENPKVVFIEISDQRLSIGSPSKIYDSLGQPVFYQASFS t WDTMIKFGDVLTVNPLVVNWRNNTVISRPGQSQCPRFNTCPEICWEGVYND glycoprotein|Gen AFLIDRINWISAGVFLDSNQTAENPVFTVFKDNEILYRAQLASEDTNAQKT e Symbol: G ITNCFLLKNKIWCISLVEIYDTGDNVIRPKLFAVKIPEQCT (Uniprot Q9IH62) 29 MLSQLQKNYLDNSNQQGDKMNNPDKKLSVNFNPLELDKGQKDLNKSYYVKN gb: JQ001776: 81 KNYNVSNLLNESLHDIKFCIYCIFSLLIIITIINIITISIVITRLKVHEEN 70- NGMESPNLQSIQDSLSSLTNMINTEITPRIGILVTATSVILSSSINYVGTK 10275|Organism: TNQLVNELKDYITKSCGFKVPELKLHECNISCADPKISKSAMYSTNAYAEL Cedar AGPPKIFCKSVSKDPDFRLKQIDYVIPVQQDRSICMNNPLLDISDGFFTYI virus|Strain HYEGINSCKKSDSFKVLLSHGEIVDRGDYRPSLYLLSSHYHPYSMQVINCV Name: CG1a|Prot PVTCNQSSFVFCHISNNTKTLDNSDYSSDEYYITYFNGIDRPKTKKIPINN ein MTADNRYIHFTFSGGGGVCLGEEFIIPVTTVINTDVFTHDYCESFNCSVQT Name: attachmen GKSLKEICSESLRSPTNSSRYNLNGIMIISQNNMTDFKIQLNGITYNKLSF t GSPGRLSKTLGQVLYYQSSMSWDTYLKAGFVEKWKPFTPNWMNNTVISRPN glycoprotein|Gen QGNCPRYHKCPEICYGGTYNDIAPLDLGKDMYVSVILDSDQLAENPEITVF e Symbol: G NSTTILYKERVSKDELNTRSTTTSCFLFLDEPWCISVLETNRFNGKSIRPE IYSYKIPKYC 30 MPQKTVEFINMNSPLERGVSTLSDKKTLNQSKITKQGYFGLGSHSERNWKK gb: NC_025256: 9 QKNQNDHYMTVSTMILEILVVLGIMFNLIVLTMVYYQNDNINQRMAELTSN 117- ITVLNLNLNQLINKIQREIIPRITLIDTATTITIPSAITYILATLTTRISE 11015|Organism:  LLPSINQKCEFKTPTLVLNDCRINCTPPLNPSDGVKMSSLATNLVAHGPSP Bat CRNFSSVPTIYYYRIPGLYNRTALDERCILNPRLTISSTKFAYVHSEYDKN Paramyxovirus CTRGFKYYELMTFGEILEGPEKEPRMFSRSFYSPTNAVNYHSCTPIVTVNE Eid_hel/GH- GYFLCLECTSSDPLYKANLSNSTFHLVILRHNKDEKIVSMPSFNLSTDQEY M74a/GHA/200 VQIIPAEGGGTAESGNLYFPCIGRLLHKRVTHPLCKKSNCSRTDDESCLKS 9|Strain YYNQGSPQHQVVNCLIRIRNAQRDNPTWDVITVDLTNTYPGSRSRIFGSFS Name: BatPV/Ei KPMLYQSSVSWHTLLQVAEITDLDKYQLDWLDTPYISRPGGSECPFGNYCP d_hel/GH- TVCWEGTYNDVYSLTPNNDLFVTVYLKSEQVAENPYFAIFSRDQILKEFPL M74a/GHA/200 DAWISSARTTTISCFMFNNEIWCIAALEITRLNDDIIRPIYYSFWLPTDCR 9|Protein TPYPHTGKMTRVPLRSTYNY Name: glycoprote in|Gene Symbol: G 31 MATNRDNTITSAEVSQEDKVKKYYGVETAEKVADSISGNKVFILMNTLLIL gb: NC_025352: 8 TGAIITITLNITNLTAAKSQQNMLKIIQDDVNAKLEMFVNLDQLVKGEIKP 716- KVSLINTAVSVSIPGQISNLQTKFLQKYVYLEESITKQCTCNPLSGIFPTS 11257}Organtsm:  GPTYPPTDKPDDDTTDDDKVDTTIKPIEYPKPDGCNRTGDHFTMEPGANFY Mojiang TVPNLGPASSNSDECYTNPSFSIGSSIYMFSQEIRKTDCTAGEILSIQIVL virus|Strain GRIVDKGQQGPQASPLLVWAVPNPKIINSCAVAAGDEMGWVLCSVTLTAAS Name: Tongguan GEPIPHMFDGFWLYKLEPDTEVVSYRITGYAYLLDKQYDSVFIGKGGGIQK 1|Protein GNDLYFQMYGLSRNRQSFKALCEHGSCLGTGGGGYQVLCDRAVMSFGSEES Name: attachmen LITNAYLKVNDLASGKPVIIGQTFPPSDSYKGSNGRMYTIGDKYGLYLAPS t SWNRYLRFGITPDISVRSTTWLKSQDPIMKILSTCTNTDRDMCPEICNTRG glycoprotein|Gen YQDIFPLSEDSEYYTYIGITPNNGGTKNFVAVRDSDGHIASIDILQNYYSI e Symbol: G TSATISCFMYKDEIWCIAITEGKKQKDNPQRIYAHSYKIRQMCYNMKSATV TVGNAKNITIRRY 32 FNTVIALLGS IVIIVMNIMI IQNYTRSTDN QAVIKDALQG NivG protein IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT IPANIGLLGS attachment KISQSTASIN ENVNEKCKFT LPPLKIHECN ISCPNPLPFR glycoprotein EYRPQTEGVS NLVGLPNNIC LQKTSNQILK PKLISYTLPV Without VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI cytoplasmic tail IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE Uniprot Q9IH62 FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 33 FNTVIALLGSI IIIVMNIMII QNYTRTTDNQ ALIKESLQSV Hendra virus G QQQIKALTDK protein Uniprot IGTEIGPKVS LIDTSSTITI PANIGLLGSK ISQSTSSINE O89343 NVNDKCKFTL Without PPLKIHECNI SCPNPLPFRE YRPISQGVSD LVGLPNQICL cytoplasmic tail QKTTSTILKP RLISYTLPIN TREGVCITDP LLAVDNGFFA YSHLEKIGSC TRGIAKQRII GVGEVLDRGD KVPSMFMTNV WTPPNPSTIH HCSSTYHEDF YYTLCAVSHV GDPILNSTSW TESLSLIRLA VRPKSDSGDY NQKYIAITKV ERGKYDKVMP YGPSGIKQGD TLYFPAVGFL PRTEFQYNDS NCPIIHCKYS KAENCRLSMG VNSKSHYILR SGLLKYNLSL GGDIILQFIE IADNRLTIGS PSKIYNSLGQ PVFYQASYSW DTMIKLGDVD TVDPLRVQWR NNSVISRPGQ SQCPRFNVCP EVCWEGTYND AFLIDRLNWV SAGVYLNSNQ TAENPVFAVF KDNEILYQVP LAEDDTNAQK TITDCFLLEN VIWCISLVEI YDTGDSVIRP KLFAVKIPAQ CSES 34 MVVILDKRCY CNLLILILMI SECSVG signal sequence 35 MKVR FENTTSDKGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA NiVG protein FNTVIALLGS IVIIVMNIMI IQNYTRSTDN QAVIKDALQG attachment IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT IPANIGLLGS glycoprotein KISQSTASIN ENVNEKCKFT LPPLKIHECN ISCPNPLPFR Truncated 45 EYRPQTEGVS NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 36 MNTTSDKGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA NiVG protein FNTVIALLGS IVIIVMNIMI IQNYTRSTDN QAVIKDALQG attachment IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT IPANIGLLGS glycoprotein KISQSTASIN ENVNEKCKFT LPPLKIHECN ISCPNPLPFR Truncated Δ10 EYRPQTEGVS NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 37 MKGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA FNTVIALLGS NiVG protein IVIIVMNIMI IQNYTRSTDN QAVIKDALQG IQQQIKGLAD attachment KIGTEIGPKV SLIDTSSTIT IPANIGLLGS KISQSTASIN glycoprotein ENVNEKCKFT LPPLKIHECN ISCPNPLPFR EYRPQTEGVS Truncated Δ15 NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 38 MSKVIKSYY GTMDIKKINE GLLDSKILSA FNTVIALLGS NiVG protein IVIIVMNIMI IQNYTRSTDN QAVIKDALQG IQQQIKGLAD attachment KIGTEIGPKV SLIDTSSTIT IPANIGLLGS KISQSTASIN glycoprotein ENVNEKCKFT LPPLKIHECN ISCPNPLPFR EYRPQTEGVS Truncated Δ20 NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 39 MSYY GTMDIKKINE GLLDSKILSA FNTVIALLGS IVIIVMNIMI NiVG protein IQNYTRSTDN QAVIKDALQG IQQQIKGLAD KIGTEIGPKV attachment SLIDTSSTIT IPANIGLLGS KISQSTASIN ENVNEKCKFT glycoprotein LPPLKIHECN ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC Truncated Δ25 LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 40 MTMDIKKINE GLLDSKILSA FNTVIALLGS IVIIVMNIMI NiVG protein IQNYTRSTDN QAVIKDALQG IQQQIKGLAD KIGTEIGPKV attachment SLIDTSSTIT IPANIGLLGS KISQSTASIN ENVNEKCKFT glycoprotein LPPLKIHECN ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC Truncated Δ30 LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 41 GGGGGS Peptide linker 42 (GGGGS)n wherein n is 1 to 10 Peptide linker 43 GGGGS Peptide linker 44 PAENKKVR FENTTSDKGK IPSKVIKSYY GTMDIKKINE NiVG protein GLLDSKILSA FNTVIALLGS IVIIVMNIMI IQNYTRSTDN attachment QAVIKDALQG IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT glycoprotein IPANIGLLGS KISQSTASIN ENVNEKCKFT LPPLKIHECN (602 aa) ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC LQKTSNQILK Without N- PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS terminal CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV methionine YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 45 KVR FENTTSDKGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA NiVG protein FNTVIALLGS IVIIVMNIMI IQNYTRSTDN QAVIKDALQG attachment IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT IPANIGLLGS glycoprotein KISQSTASIN ENVNEKCKFT LPPLKIHECN ISCPNPLPFR Truncated Δ5 EYRPQTEGVS NLVGLPNNIC LQKTSNQILK PKLISYTLPV Without N- VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI terminal IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE methionine FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 46 NTTSDKGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA NiVG protein FNTVIALLGS IVIIVMNIMI IQNYTRSTDN QAVIKDALQG attachment IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT IPANIGLLGS glycoprotein KISQSTASIN ENVNEKCKFT LPPLKIHECN ISCPNPLPFR Truncated Δ10 EYRPQTEGVS NLVGLPNNIC LQKTSNQILK PKLISYTLPV Without N- VGQSGTCITD PLLAMDEGYF AYSHLERIGS CSRGVSKQRI terminal IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE methionine FYYVLCAVST VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 47 KGK IPSKVIKSYY GTMDIKKINE GLLDSKILSA FNTVIALLGS NiVG protein IVIIVMNIMI IQNYTRSTDN QAVIKDALQG IQQQIKGLAD attachment KIGTEIGPKV SLIDTSSTIT IPANIGLLGS KISQSTASIN glycoprotein ENVNEKCKFT LPPLKIHECN ISCPNPLPFR EYRPQTEGVS Truncated 4 5 NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD Without N- PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG terminal DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST methionine VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 48 SKVIKSYY GTMDIKKINE GLLDSKILSA FNTVIALLGS NiVG protein IVIIVMNIMI IQNYTRSTDN QAVIKDALQG IQQQIKGLAD attachment KIGTEIGPKV SLIDTSSTIT IPANIGLLGS KISQSTASIN glycoprotein ENVNEKCKFT LPPLKIHECN ISCPNPLPFR EYRPQTEGVS Truncated Δ20 NLVGLPNNIC LQKTSNQILK PKLISYTLPV VGQSGTCITD Without N- PLLAMDEGYF AYSHLERIGS CSRGVSKQRI IGVGEVLDRG terminal DEVPSLFMTN VWTPPNPNTV YHCSAVYNNE FYYVLCAVST methionine VGDPILNSTY WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 49 SYY GTMDIKKINE GLLDSKILSA FNTVIALLGS IVIIVMNIMI NiVG protein IQNYTRSTDN QAVIKDALQG IQQQIKGLAD KIGTEIGPKV attachment SLIDTSSTIT IPANIGLLGS KISQSTASIN ENVNEKCKFT glycoprotein LPPLKIHECN ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC Truncated Δ25 LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF Without N- AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN terminal VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY methionine WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 50 TMDIKKINE GLLDSKILSA FNTVIALLGS IVIIVMNIMI NiVG protein IQNYTRSTDN QAVIKDALQG IQQQIKGLAD KIGTEIGPKV attachment SLIDTSSTIT IPANIGLLGS KISQSTASIN ENVNEKCKFT glycoprotein LPPLKIHECN ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC Truncated Δ30 LQKTSNQILK PKLISYTLPV VGQSGTCITD PLLAMDEGYF Without N- AYSHLERIGS CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN terminal VWTPPNPNTV YHCSAVYNNE FYYVLCAVST VGDPILNSTY methionine WSGSLMMTRL AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QC 51 KKINEGLLDSKILSA FNTVIALLGS IVIIVMNIMI IQNYTRSTDN NiVG protein QAVIKDALQG IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT attachment IPANIGLLGS KISQSTASIN ENVNEKCKFT LPPLKIHECN glycoprotein ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC LQKTSNQILK Truncated and PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS mutated CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV (E501 A, YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL W504A, Q530A, AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG E533A) NiV G DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM protein (Gc Δ GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG 34) Without N- SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW terminal RNNTVISRPG QSQCPRFNTC PAICAEGVYN DAFLIDRINW methionine ISAGVFLDSN ATAANPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 52 MADSKLVSL NNNLSGKIKD QGKVIKNYYG TMDIKKINDG Hendra virus G LLDSKILGAF protein Uniprot NTVIALLGSI IIIVMNIMII QNYTRTTDNQ ALIKESLQSV O89343 Without QQQIKALTDK IGTEIGPKVS LIDTSSTITI PANIGLLGSK N-terminal ISQSTSSINE NVNDKCKFTL methionine PPLKIHECNI SCPNPLPFRE YRPISQGVSD LVGLPNQICL QKTTSTILKP RLISYTLPIN TREGVCITDP LLAVDNGFFA YSHLEKIGSC TRGIAKQRII GVGEVLDRGD KVPSMFMTNV WTPPNPSTIH HCSSTYHEDF YYTLCAVSHV GDPILNSTSW TESLSLIRLA VRPKSDSGDY NQKYIAITKV ERGKYDKVMP YGPSGIKQGD TLYFPAVGFL PRTEFQYNDS NCPIIHCKYS KAENCRLSMG VNSKSHYILR SGLLKYNLSL GGDIILQFIE IADNRLTIGS PSKIYNSLGQ PVFYQASYSW DTMIKLGDVD TVDPLRVQWR NNSVISRPGQ SQCPRFNVCP EVCWEGTYND AFLIDRLNWV SAGVYLNSNQ TAENPVFAVF KDNEILYQVP LAEDDTNAQK TITDCFLLEN VIWCISLVEI YDTGDSVIRP KLFAVKIPAQ CSES 53 KKINEGLLDSKILSA FNTVIALLGS IVIIVMNIMI IQNYTRSTDN NiVG protein QAVIKDALQG IQQQIKGLAD KIGTEIGPKV SLIDTSSTIT attachment IPANIGLLGS KISQSTASIN ENVNEKCKFT LPPLKIHECN glycoprotein ISCPNPLPFR EYRPQTEGVS NLVGLPNNIC LQKTSNQILK Truncated (Gc Δ PKLISYTLPV VGQSGTCITD PLLAMDEGYF AYSHLERIGS 34) Without N- CSRGVSKQRI IGVGEVLDRG DEVPSLFMTN VWTPPNPNTV terminal YHCSAVYNNE FYYVLCAVST VGDPILNSTY WSGSLMMTRL methionine AVKPKSNGGG YNQHQLALRS IEKGRYDKVM PYGPSGIKQG DTLYFPAVGF LVRTEFKYND SNCPITKCQY SKPENCRLSM GIRPNSHYIL RSGLLKYNLS DGENPKVVFI EISDQRLSIG SPSKIYDSLG QPVFYQASFS WDTMIKFGDV LTVNPLVVNW RNNTVISRPG QSQCPRFNTC PEICWEGVYN DAFLIDRINW ISAGVFLDSN QTAENPVFTV FKDNEILYRA QLASEDTNAQ KTITNCFLLK NKIWCISLVE IYDTGDNVIR PKLFAVKIPE QCT 54 LSQLQKNYLDNSNQQGDKMNNPDKKLSVNFNPLELDKGQKDLNKSYYVKNK gb: JQ001776: 81 NYNVSNLLNESLHDIKFCIYCIFSLLIIITIINIITISIVITRLKVHEENN 70- GMESPNLQSIQDSLSSLTNMINTEITPRIGILVTATSVTLSSSINYVGTKT 10275|Organism:  NQLVNELKDYITKSCGFKVPELKLHECNISCADPKISKSAMYSTNAYAELA Cedar GPPKIFCKSVSKDPDFRLKQIDYVIPVQQDRSICMNNPLLDISDGFFTYIH virus|Strain YEGINSCKKSDSFKVLLSHGEIVDRGDYRPSLYLLSSHYHPYSMQVINCVP Name: CG1a|Prot VTCNQSSFVFCHISNNTKTLDNSDYSSDEYYITYFNGIDRPKTKKIPINNM ein TADNRYIHFTFSGGGGVCLGEEFIIPVTTVINTDVFTHDYCESFNCSVQTG Name: attachmen KSLKEICSESLRSPTNSSRYNLNGIMIISQNNMTDFKIQLNGITYNKLSFG t SPGRLSKTLGQVLYYQSSMSWDTYLKAGFVEKWKPFTPNWMNNTVISRPNQ glycoprotein|Gen GNCPRYHKCPEICYGGTYNDIAPLDLGKDMYVSVILDSDQLAENPEITVFN e Symbol: G STTILYKERVSKDELNTRSTTTSCFLFLDEPWCISVLETNRFNGKSIRPEI Without N- YSYKIPKYC terminal methionine 55 PQKTVEFINMNSPLERGVSTLSDKKTLNQSKITKQGYFGLGSHSERNWKKQ gb: NC_025256: 9 KNQNDHYMTVSTMILEILVVLGIMFNLIVLTMVYYQNDNINQRMAELTSNI 117- TVLNLNLNQLTNKIQREIIPRITLIDTATTITIPSAITYILATLTTRISEL 11015|Organism:  LPSINQKCEFKTPTLVLNDCRINCTPPLNPSDGVKMSSLATNLVAHGPSPC Bat RNFSSVPTIYYYRIPGLYNRTALDERCILNPRLTISSTKFAYVHSEYDKNC Paramyxovirus TRGFKYYELMTFGEILEGPEKEPRMFSRSFYSPTNAVNYHSCTPIVTVNEG Eid_hel/GH- YFLCLECTSSDPLYKANLSNSTFHLVILRHNKDEKIVSMPSFNLSTDQEYV M74a/GHA/200 QIIPAEGGGTAESGNLYFPCIGRLLHKRVTHPLCKKSNCSRTDDESCLKSY 9|Strain YNQGSPQHQVVNCLIRIRNAQRDNPTWDVITVDLTNTYPGSRSRIFGSFSK Name: BatPV/Ei PMLYQSSVSWHTLLQVAEITDLDKYQLDWLDTPYISRPGGSECPFGNYCPT d_hel/GH- VCWEGTYNDVYSLTPNNDLFVTVYLKSEQVAENPYFAIFSRDQILKEFPLD M74a/GHA/200 AWISSARTTTISCFMFNNEIWCIAALEITRLNDDIIRPIYYSFWLPTDCRT 9|Protein PYPHTGKMTRVPLRSTYNY Name: glycoprote in|Gene Symbol: G Without N- terminal methionine 56 ATNRDNTITSAEVSQEDKVKKYYGVETAEKVADSISGNKVFILMNTLLILT gb: NC_025352: 8 GAIITITLNITNLTAAKSQQNMLKIIQDDVNAKLEMFVNLDQLVKGEIKPK 716- VSLINTAVSVSIPGQISNLQTKFLQKYVYLEESITKQCTCNPLSGIFPTSG 11257|Organism:  PTYPPTDKPDDDTTDDDKVDTTIKPIEYPKPDGCNRTGDHFTMEPGANFYT Mojiang VPNLGPASSNSDECYTNPSFSIGSSIYMFSQEIRKTDCTAGEILSIQIVLG virus|Strain RIVDKGQQGPQASPLLVWAVPNPKIINSCAVAAGDEMGWVLCSVTLTAASG Name: Tongguan EPIPHMFDGFWLYKLEPDTEVVSYRITGYAYLLDKQYDSVFIGKGGGIQKG 1|Protein NDLYFQMYGLSRNRQSFKALCEHGSCLGTGGGGYQVLCDRAVMSFGSEESL Name: attachmen ITNAYLKVNDLASGKPVIIGQTFPPSDSYKGSNGRMYTIGDKYGLYLAPSS t WNRYLRFGITPDISVRSTTWLKSQDPIMKILSTCTNTDRDMCPEICNTRGY glycoprotein|lGen QDIFPLSEDSEYYTYIGITPNNGGTKNFVAVRDSDGHIASIDILQNYYSIT e Symbol: G SATISCFMYKDEIWCIAITEGKKQKDNPQRIYAHSYKIRQMCYNMKSATVT Without N- VGNAKNITIRRY terminal methionine 57 DFDKLNKIGVVQGRVLNYKIKGDPMTKDLVLKFIPNIVNITECVREPLSRY gb: JQ001776: 61 NETVRRLLLPIHNMLGLYLNNTNAKMTGLMIAGVIMGGIAIGIATAAQITA 29- GFALYEAKKNTENIQKLTDSIMKTQDSIDKLTDSVGTSILILNKLQTYINN 8166|Organism:  QLVPNLELLSCRQNKIEFDLMLTKYLVDLMTVIGPNINNPVNKDMTIQSLS Cedar LLFDGNYDIMMSELGYTPQDFLDLIESKSITGQIIYVDMENLYVVIRTYLP virus|Strain TLIEVPDAQIYEFNKITMSSNGGEYLSTIPNFILIRGNYMSNIDVATCYMT Name: CG1a|Prot KASVICNQDYSLPMSQNLRSCYQGETEYCPVEAVIASHSPRFALTNGVIFA ein Name: fusion NCINTICRCQDNGKTITQNINQFVSMIDNSTCNDVMVDKFTIKVGKYMGRK glycoprotein|Gen DINNINIQIGPQIIIDKVDLSNEINKMNQSLKDSIFYLREAKRILDSVNIS e Symbol: F LISPSVQLFLIIISVLSFIILLIIIVYLYCKSKHSYKYNKFIDDPDYYNDY (without signal KRERINGKASKSNNIYYVGD sequence) 58 SRALLRETDNYSNGLIVENLVRNCHHPSKNNLNYTKTQKRDSTIPYRVEER gb: NC_025256: 6 KGHYPKIKHLIDKSYKHIKRGKRRNGHNGNIITIILLLILILKTQMSEGAI 865- HYETLSKIGLIKGITREYKVKGTPSSKDIVIKLIPNVTGLNKCTNISMENY 8853|Organism:  KEQLDKILIPINNIIELYANSTKSAPGNARFAGVIIAGVALGVAAAAQITA Bat GIALHEARQNAERINLLKDSISATNNAVAELQEATGGIVNVITGMQDYINT Paramyxovirus NLVPQIDKLQCSQIKTALDISLSQYYSEILTVFGPNLQNPVTTSMSIQAIS Eid_hel/GH- QSFGGNIDLLLNLLGYTANDLLDLLESKSITGQITYINLEHYFMVIRVYYP M74a/GHA/200 IMTTISNAYVQELIKISFNVDGSEWVSLVPSYILIRNSYLSNIDISECLIT 9|Strain KNSVICRHDFAMPMSYTLKECLTGDTEKCPREAVVTSYVPRFAISGGVIYA Name: BatPV/Ei NCLSTTCQCYQTGKVIAQDGSQTLMMIDNQTCSIVRIEEILISTGKYLGSQ d_hel/GH- EYNTMHVSVGNPVFTDKLDITSQISNINQSIEQSKFYLDKSKAILDKINLN M74a/GHA/200 LIGSVPISILFIIAILSLILSIITFVIVMIIVRRYNKYTPLINSDPSSRRS 9|Protein TIQDVYIIPNPGEHSIRSAARSIDRDRD Name: fusion proteinlGene Symbol: F (without signal sequence) 59 ILHY EKLSKIGLVK GITRKYKIKS Hendra virus F NPLTKDIVIK MIPNVSNVSK CTGTVMENYK SRLTGILSPI protein KGAIELYNNN Uniprot O89342 THDLVGDVKL AGVVMAGIAI GIATAAQITA GVALYEAMKN (without signal ADNINKLKSS sequence) IESTNEAVVK LQETAEKTVY VLTALQDYIN TNLVPTIDQI SCKQTELALD LALSKYLSDL LFVFGPNLQD PVSNSMTIQA ISQAFGGNYE TLLRTLGYAT EDFDDLLESD SIAGQIVYVD LSSYYIIVRV YFPILTEIQQ AYVQELLPVS FNNDNSEWIS IVPNFVLIRN TLISNIEVKY CLITKKSVIC NQDYATPMTA SVRECLTGST DKCPRELVVS SHVPRFALSG GVLFANCISV TCQCQTTGRA ISQSGEQTLL MIDNTTCTTV VLGNIIISLG KYLGSINYNS ESIAVGPPVY TDKVDISSQI SSMNQSLQQS KDYIKEAQKI LDTVNPSLIS MLSMIILYVL SIAALCIGLI TFISFVIVEK KRGNYSRLDD RQVRPVSNGD LYYIGT 60 IHYDSLSKVGVIKGLTYNYKIKGSPSTKLMVVKLIPNIDSVKNCTQKQYDE gb: NC_025352: 5 YKNLVRKALEPVKMAIDTMLNNVKSGNNKYRFAGAIMAGVALGVATAATVT 950- AGIALHRSNENAQAIANMKSAIQNTNEAVKQLQLANKQTLAVIDTIRGEIN 8712|Organism: NNIIPVINQLSCDTIGLSVGIRLTQYYSEIITAFGPALQNPVNTRITIQAI Mojiang SSVFNGNFDELLKIMGYTSGDLYEILHSELIRGNIIDVDVDAGYIALEIEF virus|Strain PNLTLVPNAVVQELMPISYNIDGDEWVILVPRFVLTRTTLLSNIDTSRCTI Name: Tongguan TDSSVICDNDYALPMSHELIGCLQGDTSKCAREKVVSSYVPKFALSDGLVY 1|Protein ANCLNTICRCMDTDTPISQSLGATVSLLDNKRCSVYQVGDVLISVGSYLGD Name: fusion GEYNADNVELGPPIVIDKIDIGNQLAGINQTLQEAEDYIEKSEEFLKGVNP protein|Gene SIITLGSMVVLYIFMILIAIVSVIALVLSIKLTVKGNVVRQQFTYTQHVPS Symbol: F MENINYVSH (without signal sequence) 61 MLFNLRILLNNAAFRNGHNFMVRNFRCGQPLQNKVQLKGRDLLTL OTC KNFTGEEIKYMLWLSADLKFRIKQKGEYLPLLQGKSLGMIFEKRSTR TRLSTETGFALLGGHPCFLTTQDIHLGVNESLTDTARVLSSMADAVL ARVYKQSDLDTLAKEASIPIINGLSDLYHPIQILADYLTLQEHYSSLK GLTLSWIGDGNNILHSIMMSAAKFGMHLQAATPKGYEPDASVTKL AEQYAKENGTKLLLTNDPLEAAHGGNVLITDTWISMGQEEEKKKR LQAFQGYQVTMKTAKVAASDWTFLHCLPRKPEEVDDEVFYSPRSL VFPEAENRKWTIMAVMVSLLTDYSPQLQKPKF 62 MTRILTAFKVVRTLKTGFGFTNVTAHQKWKFSRPGIRLLSVKAQTA CPS1 HIVLEDGTKMKGYSFGHPSSVAGEVVFNTGLGGYPEAITDPAYKGQ ILTMANPIIGNGGAPDTTALDELGLSKYLESNGIKVSGLLVLDYSKD YNHWLATKSLGQWLQEEKVPAIYGVDTRMLTKIIRDKGTMLGKIEF EGQPVDFVDPNKQNLIAEVSTKDVKVYGKGNPTKVVAVDCGIKNN VIRLLVKRGAEVHLVPWNHDFTKMEYDGILIAGGPGNPALAEPLIQ NVRKILESDRKEPLFGISTGNLITGLAAGAKTYKMSMANRGQNQPV LNITNKQAFITAQNHGYALDNTLPAGWKPLFVNVNDQTNEGIMHES KPFFAVQFHPEVTPGPIDTEYLFDSFFSLIKKGKATTITSVLPKPALVA SRVEVSKVLILGSGGLSIGQAGEFDYSGSQAVKAMKEENVKTVLMN PNIASVQTNEVGLKQADTVYFLPITPQFVTEVIKAEQPDGLILGMGG QTALNCGVELFKRGVLKEYGVKVLGTSVESIMATEDRQLFSDKLNE INEKIAPSFAVESIEDALKAADTIGYPVMIRSAYALGGLGSGICPNRE TLMDLSTKAFAMTNQILVEKSVTGWKEIEYEVVRDADDNCVTVCN MENVDAMGVHTGDSVVVAPAQTLSNAEFQMLRRTSINVVRHLGIV GECNIQFALHPTSMEYCIIEVNARLSRSSALASKATGYPLAFIAAKIA LGIPLPEIKNVVSGKTSACFEPSLDYMVTKIPRWDLDRFHGTSSRIGS SMKSVGEVMAIGRTFEESFQKALRMCHPSIEGFTPRLPMNKEWPSN LDLRKELSEPSSTRIYAIAKAIDDNMSLDEIEKLTYIDKWFLYKMRDI LNMEKTLKGLNSESMTEETLKRAKEIGFSDKQISKCLGLTEAQTREL RLKKNIHPWVKQIDTLAAEYPSVTNYLYVTYNGQEHDVNFDDHGM MVLGCGPYHIGSSVEFDWCAVSSIRTLRQLGKKTVVVNCNPETVST DFDECDKLYFEELSLERILDIYHQEACGGCIISVGGQIPNNLAVPLYK NGVKIMGTSPLQIDRAEDRSIFSAVLDELKVAQAPWKAVNTLNEAL EFAKSVDYPCLLRPSYVLSGSAMNVVFSEDEMKKFLEEATRVSQEH PVVLTKFVEGAREVEMDAVGKDGRVISHAISEHVEDAGVHSGDAT LMLPTQTISQGAIEKVKDATRKIAKAFAISGPFNVQFLVKGNDVLVI ECNLRASRSFPFVSKTLGVDFIDVATKVMIGENVDEKHLPTLDHPIIP ADYVAIKAPMFSWPRLRDADPILRCEMASTGEVACFGEGIHTAFLK AMLSTGFKIPQKGILIGIQQSFRPRFLGVAEQLHNEGFKLFATEATSD WLNANNVPATPVAWPSQEGQNPSLSSIRKLIRDGSIDLVINLPNNNT KFVHDNYVIRRTAVDSGIPLLTNFQVTKLFAEAVQKSRKVDSKSLF HYRQYSAGKAA 63 MATALMAVVLRAAAVAPRLRGRGGTGGARRLSCGARRRAARGTS NAGS PGRRLSTAWSQPQPPPEEYAGADDVSQSPVAEEPSWVPSPRPPVPHE SPEPPSGRSLVQRDIQAFLNQCGASPGEARHWLTQFQTCHHSADKPF AVIEVDEEVLKCQQGVSSLAFALAFLQRMDMKPLVVLGLPAPTAPS GCLSFWEAKAQLAKSCKVLVDALRHNAAAAVPFFGGGSVLRAAEP APHASYGGIVSVETDLLQWCLESGSIPILCPIGETAARRSVLLDSLEV TASLAKALRPTKIIFLNNTGGLRDSSHKVLSNVNLPADLDLVCNAE WVSTKERQQMRLIVDVLSRLPHHSSAVITAASTLLTELFSNKGSGTL FKNAERMLRVRSLDKLDQGRLVDLVNASFGKKLRDDYLASLRPRL HSIYVSEGYNAAAILTMEPVLGGTPYLDKFVVSSSRQGQGSGQMLW ECLRRDLQTLFWRSRVTNPINPWYFKHSDGSFSNKQWIFFWFGLAD IRDSYELVNHAKGLPDSFHKPASDPGS 64 MAVAIAAARVWRLNRGLSQAALLLLRQPGARGLARSHPPRQQQQF BCKDHA SSLDDKPQFPGASAEFIDKLEFIQPNVISGIPIYRVMDRQGQIINPSEDP HLPKEKVLKLYKSMTLLNTMDRILYESQRQGRISFYMTNYGEEGTH VGSAAALDNTDLVFGQYREAGVLMYRDYPLELFMAQCYGNISDLG KGRQMPVHYGCKERHFVTISSPLATQIPQAVGAAYAAKRANANRV VICYFGEGAASEGDAHAGFNFAATLECPIIFFCRNNGYAISTPTSEQY RGDGIAARGPGYGIMSIRVDGNDVFAVYNATKEARRRAVAENQPF LIEAMTYRIGHHSTSDDSSAYRSVDEVNYWDKQDHPISRLRHYLLS QGWWDEEQEKAWRKQSRRKVMEAFEQAERKPKPNPNLLFSDVYQ EMPAQLRKQQESLARHLQTYGEHYPLDHFDK 65 MAVVAAAAGWLLRLRAAGAEGHWRRLPGAGLARGFLHPAATVE BCKDHB DAAQRRQVAHFTFQPDPEPREYGQTQKMNLFQSVTSALDNSLAKD PTAVIFGEDVAFGGVFRCTVGLRDKYGKDRVFNTPLCEQGIVGFGIG IAVTGATAIAEIQFADYIFPAFDQIVNEAAKYRYRSGDLFNCGSLTIR SPWGCVGHGALYHSQSPEAFFAHCPGIKVVIPRSPFQAKGLLLSCIE DKNPCIFFEPKILYRAAAEEVPIEPYNIPLSQAEVIQEGSDVTLVAWG TQVHVIREVASMAKEKLGVSCEVIDLRTIIPWDVDTICKSVIKTGRLL ISHEAPLTGGFASEISSTVQEECFLNLEAPISRVCGYDTPFPHIFEPFYI PDKWKCYDALRKMINY 66 MAAVRMLRTWSRNAGKLICVRYFQTCGNVHVLKPNYVCFFGYPSF DBT KYSHPHHFLKTTAALRGQVVQFKLSDIGEGIREVTVKEWYVKEGDT VSQFDSICEVQSDKASVTITSRYDGVIKKLYYNLDDIAYVGKPLVDI ETEALKDSEEDVVETPAVSHDEHTHQEIKGRKTLATPAVRRLAMEN NIKLSEVVGSGKDGRILKEDILNYLEKQTGAILPPSPKVEIMPPPPKP KDMTVPILVSKPPVFTGKDKTEPIKGFQKAMVKTMSAALKIPHFGY CDEIDLTELVKLREELKPIAFARGIKLSFMPFFLKAASLGLLQFPILNA SVDENCQNITYKASHNIGIAMDTEQGLIVPNVKNVQICSIFDIATELN RLQKLGSVGQLSTTDLTGGTFTLSNIGSIGGTFAKPVIMPPEVAIGAL GSIKAIPRFNQKGEVYKAQIMNVSWSADHRVIDGATMSRFSNLWKS YLENPAFMLLDLK 67 MQSWSRVYCSLAKRGHFNRISHGLQGLSAVPLRTYADQPIDADVTV DLD IGSGPGGYVAAIKAAQLGFKTVCIEKNETLGGTCLNVGCIPSKALLN NSHYYHMAHGKDFASRGIEMSEVRLNLDKMMEQKSTAVKALTGGI AHLFKQNKVVHVNGYGKITGKNQVTATKADGGTQVIDTKNILIATG SEVTPFPGITIDEDTIVSSTGALSLKKVPEKMVVIGAGVIGVELGSVW QRLGADVTAVEFLGHVGGVGIDMEISKNFQRILQKQGFKFKLNTKV TGATKKSDGKIDVSIEAASGGKAEVITCDVLLVCIGRRPFTKNLGLE ELGIELDPRGRIPVNTRFQTKIPNIYAIGDVVAGPMLAHKAEDEGIIC VEGMAGGAVHIDYNCVPSVIYTHPEVAWVGKSEEQLKEEGIEYKV GKFPFAANSRAKTNADTDGMVKILGQKSTDRVLGAHILGPGAGEM VNEAALALEYGASCEDIARVCHAHPTLSEAFREANLAASFGKSINF 68 MLRAKNQLFLLSPHYLRQVKESSGSRLIQQRLLHQQQPLHPEWAAL MUT AKKQLKGKNPEDLIWHTPEGISIKPLYSKRDTMDLPEELPGVKPFTR GPYPTMYTFRPWTIRQYAGFSTVEESNKFYKDNIKAGQQGLSVAFD LATHRGYDSDNPRVRGDVGMAGVAIDTVEDTKILFDGIPLEKMSVS MTMNGAVIPVLANFIVTGEEQGVPKEKLTGTIQNDILKEFMVRNTYI FPPEPSMKIIADIFEYTAKHMPKFNSISISGYHMQEAGADAILELAYT LADGLEYSRTGLQAGLTIDEFAPRLSFFWGIGMNFYMEIAKMRAGR RLWAHLIEKMFQPKNSKSLLLRAHCQTSGWSLTEQDPYNNIVRTAI EAMAAVFGGTQSLHTNSFDEALGLPTVKSARIARNTQIIIQEESGIPK VADPWGGSYMMECLTNDVYDAALKLINEIEEMGGMAKAVAEGIP KLRIEECAARRQARIDSGSEVIVGVNKYQLEKEDAVEVLAIDNTSVR NRQIEKLKKIKSSRDQALAERCLAALTECAASGDGNILALAVDASR ARCTVGEITDALKKVFGEHKANDRMVSGAYRQEFGESKEITSAIKR VHKFMEREGRRPRLLVAKMGQDGHDRGAKVIATGFADLGFDVDIG PLFQTPREVAQQAVDADVHAVGISTLAAGHKTLVPELIKELNSLGRP DILVMCGGVIPPQDYEFLFEVGVSNVFGPGTRIPKAAVQVLDDIEKC LEKKQQSV 69 MPMLLPHPHQHFLKGLLRAPFRCYHFIFHSSTHLGSGIPCAQPFNSL MMAA GLHCTKWMLLSDGLKRKLCVQTTLKDHTEGLSDKEQRFVDKLYTG LIQGQRACLAEAITLVESTHSRKKELAQVLLQKVLLYHREQEQSNK GKPLAFRVGLSGPPGAGKSTFIEYFGKMLTERGHKLSVLAVDPSSCT SGGSLLGDKTRMTELSRDMNAYIRPSPTRGTLGGVTRTTNEAILLCE GAGYDIILIETVGVGQSEFAVADMVDMFVLLLPPAGGDELQGIKRGI IEMADLVAVTKSDGDLIVPARRIQAEYVSALKLLRKRSQVWKPKVI RISARSGEGISEMWDKMKDFQDLMLASGELTAKRRKQQKVWMWN LIQESVLEHFRTHPTVREQIPLLEQKVLIGALSPGLAADFLLKAFKSR D 70 MAVCGLGSRLGLGSRLGLRGCFGAARLLYPRFQSRGPQGVEDGDR MMAB PQPSSKTPRIPKIYTKTGDKGFSSTFTGERRPKDDQVFEAVGTTDELS SAIGFALELVTEKGHTFAEELQKIQCTLQDVGSALATPCSSAREAHL KYTTFKAGPILELEQWIDKYTSQLPPLTAFILPSGGKISSALHFCRAV CRRAERRVVPLVQMGETDANVAKFLNRLSDYLFTLARYAAMKEG NQEKIYMKNDPSAESEGL 71 MFDRALKPFLQSCHLRMLTDPVDQCVAYHLGRVRESLPELQIEIIAD MMACHC YEVHPNRRPKILAQTAAHVAGAAYYYQRQDVEADPWGNQRISGVC IHPRFGGWFAIRGVVLLPGIEVPDLPPRKPHDCVPTRADRIALLEGFN FHWRDWTYRDAVTPQERYSEEQKAYFSTPPAQRLALLGLAQPSEKP SSPSPDLPFTTPAPKKPGNPSRARSWLSPRVSPPASPGP 72 MANVLCNRARLVSYLPGFCSLVKRVVNPKAFSTAGSSGSDESHVA MMADHC AAPPDICSRTVWPDETMGPFGPQDQRFQLPGNIGFDCHLNGTASQK KSLVHKTLPDVLAEPLSSERHEFVMAQYVNEFQGNDAPVEQEINSA ETYFESARVECAIQTCPELLRKDFESLFPEVANGKLMILTVTQKTKN DMTVWSEEVEIEREVLLEKFINGAKEICYALRAEGYWADFIDPSSGL AFFGPYTNNTLFETDERYRHLGFSVDDLGCCKVIRHSLWGTHVVVG SIFTNATPDSHIMKKLSGN 73 MARVLKAAAANAVGLFSRLQAPIPTVRASSTSQPLDQVTGSVWNL MCEE GRLNHVAIAVPDLEKAAAFYKNILGAQVSEAVPLPEHGVSVVFVNL GNTKMELLHPLGRDSPIAGFLQKNKAGGMHHICIEVDNINAAVMDL KKKKIRSLSEEVKIGAHGKPVIFLHPKDCGGVLVELEQA 74 MAGFWVGTAPLVAAGRRGRWPPQQLMLSAALRTLKHVLYYSRQC PCCA LMVSRNLGSVGYDPNEKTFDKILVANRGEIACRVIRTCKKMGIKTV AIHSDVDASSVHVKMADEAVCVGPAPTSKSYLNMDAIMEAIKKTR AQAVHPGYGFLSENKEFARCLAAEDVVFIGPDTHAIQAMGDKIESK LLAKKAEVNTIPGFDGVVKDAEEAVRIAREIGYPVMIKASAGGGGK GMRIAWDDEETRDGFRLSSQEAASSFGDDRLLIEKFIDNPRHIEIQVL GDKHGNALWLNERECSIQRRNQKVVEEAPSIFLDAETRRAMGEQA VALARAVKYSSAGTVEFLVDSKKNFYFLEMNTRLQVEHPVTECITG LDLVQEMIRVAKGYPLRHKQADIRINGWAVECRVYAEDPYKSFGLP SIGRLSQYQEPLHLPGVRVDSGIQPGSDISIYYDPMISKLITYGSDRTE ALKRMADALDNYVIRGVTHNIALLREVIINSRFVKGDISTKFLSDVY PDGFKGHMLTKSEKNQLLAIASSLFVAFQLRAQHFQENSRMPVIKP DIANWELSVKLHDKVHTVVASNNGSVFSVEVDGSKLNVTSTWNLA SPLLSVSVDGTQRTVQCLSREAGGNMSIQFLGTVYKVNILTRLAAEL NKFMLEKVTEDTSSVLRSPMPGVVVAVSVKPGDAVAEGQEICVIEA MKMQNSMTAGKTGTVKSVHCQAGDTVGEGDLLVELE 75 MAAALRVAAVGARLSVLASGLRAAVRSLCSQATSVNERIENKRRT PCCB ALLGGGQRRIDAQHKRGKLTARERISLLLDPGSFVESDMFVEHRCA DFGMAADKNKFPGDSVVTGRGRINGRLVYVFSQDFTVFGGSLSGA HAQKICKIMDQAITVGAPVIGLNDSGGARIQEGVESLAGYADIFLRN VTASGVIPQISLIMGPCAGGAVYSPALTDFTFMVKDTSYLFITGPDV VKSVTNEDVTQEELGGAKTHTTMSGVAHRAFENDVDALCNLRDFF NYLPLSSQDPAPVRECHDPSDRLVPELDTIVPLESTKAYNMVDIIHSV VDEREFFEIMPNYAKNIIVGFARMNGRTVGIVGNQPKVASGCLDINS SVKGARFVRFCDAFNIPLITFVDVPGFLPGTAQEYGGIIRHGAKLLY AFAEATVPKVTVITRKAYGGAYDVMSSKHLCGDTNYAWPTAEIAV MGAKGAVEIIFKGHENVEAAQAEYIEKFANPFPAAVRGFVDDIIQPS STRARICCDLDVLASKKVQRPWRKHANIPL 76 MAVESQGGRPLVLGLLLCVLGPVVSHAGKILLIPVDGSHWLSMLGA UGT1A1 IQQLQQRGHEIVVLAPDASLYIRDGAFYTLKTYPVPFQREDVKESFV SLGHNVFENDSFLQRVIKTYKKIKKDSAMLLSGCSHLLHNKELMAS LAESSFDVMLTDPFLPCSPIVAQYLSLPTVFFLHALPCSLEFEATQCP NPFSYVPRPLSSHSDHMTFLQRVKNMLIAFSQNFLCDVVYSPYATL ASEFLQREVTVQDLLSSASVWLFRSDFVKDYPRPIMPNMVFVGGIN CLHQNPLSQEFEAYINASGEHGIVVFSLGSMVSEIPEKKAMAIADAL GKIPQTVLWRYTGTRPSNLANNTILVKWLPQNDLLGHPMTRAFITH AGSHGVYESICNGVPMVMMPLFGDQMDNAKRMETKGAGVTLNVL EMTSEDLENALKAVINDKSYKENIMRLSSLHKDRPVEPLDLAVFWV EFVMRHKGAPHLRPAAHDLTWYQYHSLDVIGFLLAVVLTVAFITFK CCAYGYRKCLGKKGRVKKAHKSKTH 77 MSSKGSVVLAYSGGLDTSCILVWLKEQGYDVIAYLANIGQKEDFEE ASS1 ARKKALKLGAKKVFIEDVSREFVEEFIWPAIQSSALYEDRYLLGTSL ARPCIARKQVEIAQREGAKYVSHGATGKGNDQVRFELSCYSLAPQI KVIAPWRMPEFYNRFKGRNDLMEYAKQHGIPIPVTPKNPWSMDEN LMHISYEAGILENPKNQAPPGLYTKTQDPAKAPNTPDILEIEFKKGVP VKVTNVKDGTTHQTSLELFMYLNEVAGKHGVGRIDIVENRFIGMKS RGIYETPAGTILYHAHLDIEAFTMDREVRKIKQGLGLKFAELVYTGF WHSPECEFVRHCIAKSQERVEGKVQVSVLKGQVYILGRESPLSLYN EELVSMNVQGDYEPTDATGFININSLRLKEYHRLQSKVTAK 78 MSTAVLENPGLGRKLSDFGQETSYIEDNCNQNGAISLIFSLKEEVGA PAH LAKVLRLFEENDVNLTHIESRPSRLKKDEYEFFTHLDKRSLPALTNII KILRHDIGATVHELSRDKKKDTVPWFPRTIQELDRFANQILSYGAEL DADHPGFKDPVYRARRKQFADIAYNYRHGQPIPRVEYMEEEKKTW GTVFKTLKSLYKTHACYEYNHIFPLLEKYCGFHEDNIPQLEDVSQFL QTCTGFRLRPVAGLLSSRDFLGGLAFRVFHCTQYIRHGSKPMYTPEP DICHELLGHVPLFSDRSFAQFSQEIGLASLGAPDEYIEKLATIYWFTV EFGLCKQGDSIKAYGAGLLSSFGELQYCLSEKPKLLPLELEKTAIQN YTVTEFQPLYYVAESFNDAKEKVRNFAATIPRPFSVRYDPYTQRIEV LDNTQQLKILADSINSEIGILCSALQKIK 79 MAKTLSQAQSKTSSQQFSFTGNSSANVIIGNQKLTINDVARVARNGT PAL LVSLTNNTDILQGIQASCDYINNAVESGEPIYGVTSGFGGMANVAIS REQASELQTNLVWFLKTGAGNKLPLADVRAAMLLRANSHMRGAS GIRLELIKRMEIFLNAGVTPYVYEFGSIGASGDLVPLSYITGSLIGLDP SFKVDFNGKEMDAPTALRQLNLSPLTLLPKEGLAMMNGTSVMTGI AANCVYDTQILTAIAMGVHALDIQALNGTNQSFHPFIHNSKPHPGQL WAADQMISLLANS QLVRDELDGKHDYRDHELIQDRYSLRCLPQYLGPIVDGISQIAKQIEI EINSVTDNPLIDVDNQASYHGGNFLGQYVGMGMDHLRYYIGLLAK HLDVQIALLASPEFSNGLPPSLLGNRERKVNMGLKGLQICGNSIMPL LTFYGNSIADRFPTHAEQFNQNINSQGYTSATLARRSVDIFQNYVAI ALMFGVQAVDLRTYKKTGHYDARASLSPATERLYSAVRHVVGQKP TSDRPYIWNDNEQGLDEHIARISADIAAGGVIVQAVQDILPSLH 80 MSTERDSETTFDEDSQPNDEVVPYSDDETEDELDDQGSAVEPEQNR ATP8B1 VNREAEENREPFRKECTWQVKANDRKYHEQPHFMNTKFLCIKESK YANNAIKTYKYNAFTFIPMNLFEQFKRAANLYFLALLILQAVPQIST LAWYTTLVPLLVVLGVTAIKDLVDDVARHKMDKEINNRTCEVIKD GRFKVAKWKEIQVGDVIRLKKNDFVPADILLLSSSEPNSLCYVETAE LDGETNLKFKMSLEITDQYLQREDTLATFDGFIECEEPNNRLDKFTG TLFWRNTSFPLDADKILLRGCVIRNTDFCHGLVIFAGADTKIMKNSG KTRFKRTKIDYLMNYMVYTIFVVLILLSAGLAIGHAYWEAQVGNSS WYLYDGEDDTPSYRGFLIFWGYIIVLNTMVPISLYVSVEVIRLGQSH FINWDLQMYYAEKDTPAKARTTTLNEQLGQIHYIFSDKTGTLTQNI MTFKKCCINGQIYGDHRDASQHNHNKIEQVDFSWNTYADGKLAFY DHYLIEQIQSGKEPEVRQFFFLLAVCHTVMVDRTDGQLNYQAASPD EGALVNAARNFGFAFLARTQNTITISELGTERTYNVLAILDFNSDRK RMSIIVRTPEGNIKLYCKGADTVIYERLHRMNPTKQETQDALDIFAN ETLRTLCLCYKEIEEKEFTEWNKKFMAASVASTNRDEALDKVYEEI EKDLILLGATAIEDKLQDGVPETISKLAKADIKIWVLTGDKKETAENI GFACELLTEDTTICYGEDINSLLHARMENQRNRGGVYAKFAPPVQE SFFPPGGNRALIITGSWLNEILLEKKTKRNKILKLKFPRTEEERRMRT QSKRRLEAKKEQRQKNFVDLACECSAVICCRVTPKQKAMVVDLVK RYKKAITLAIGDGANDVNMIKTAHIGVGISGQEGMQAVMSSDYSFA QFRYLQRLLLVHGRWSYIRMCKFLRYFFYKNFAFTLVHFWYSFFNG YSAQTAYEDWFITLYNVLYTSLPVLLMGLLDQDVSDKLSLRFPGLY IVGQRDLLFNYKRFFVSLLHGVLTSMILFFIPLGAYLQTVGQDGEAP SDYQSFAVTIASALVITVNFQIGLDTSYWTFVNAFSIFGSIALYFGIMF DFHSAGIHVLFPSAFQFTGTASNALRQPYIWLTIILAVAVCLLPVVAI RFLSMTIWPSESDKIQKHRKRLKAEEQWQRRQQVFRRGVSTRRSAY AFSHQRGYADLISSGRSIRKKRSPLDAIVADGTAEYRRTGDS 81 MSDSVILRSIKKFGEENDGFESDKSYNNDKKSRLQDEKKGDGVRVG ABCB11 FFQLFRFSSSTDIWLMFVGSLCAFLHGIAQPGVLLIFGTMTDVFIDYD VELQELQIPGKACVNNTIVWTNSSLNQNMTNGTRCGLLNIESEMIKF ASYYAGIAVAVLITGYIQICFWVIAAARQIQKMRKFYFRRIMRMEIG WFDCNSVGELNTRFSDDINKINDAIADQMALFIQRMTSTICGFLLGF FRGWKLTLVIISVSPLIGIGAATIGLSVSKFTDYELKAYAKAGVVAD EVISSMRTVAAFGGEKREVERYEKNLVFAQRWGIRKGIVMGFFTGF VWCLIFLCYALAFWYGSTLVLDEGEYTPGTLVQIFLSVIVGALNLGN ASPCLEAFATGRAAATSIFETIDRKPIIDCMSEDGYKLDRIKGEIEFHN VTFHYPSRPEVKILNDLNMVIKPGEMTALVGPSGAGKSTALQLIQRF YDPCEGMVTVDGHDIRSLNIQWLRDQIGIVEQEPVLFSTTIAENIRYG REDATMEDIVQAAKEANAYNFIMDLPQQFDTLVGEGGGQMSGGQ KQRVAIARALIRNPKILLLDMATSALDNESEAMVQEVLSKIQHGHTII SVAHRLSTVRAADTIIGFEHGTAVERGTHEELLERKGVYFTLVTLQS QGNQALNEEDIKDATEDDMLARTFSRGSYQDSLRASIRQRSKSQLS YLVHEPPLAVVDHKSTYEEDRKDKDIPVQEEVEPAPVRRILKFSAPE WPYMLVGSVGAAVNGTVTPLYAFLFSQILGTFSIPDKEEQRSQINGV CLLFVAMGCVSLFTQFLQGYAFAKSGELLTKRLRKFGFRAMLGQDI AWFDDLRNSPGALTTRLATDASQVQGAAGSQIGMIVNSFTNVTVA MIIAFSFSWKLSLVILCFFPFLALSGATQTRMLTGFASRDKQALEMV GQITNEALSNIRTVAGIGKERRHEALETELEKPFKTAIQKANIYGFCF AFAQCIMFIANSASYRYGGYLISNEGLHFSYVFRVISAVVLSATALG RAFSYTPSYAKAKISAARFFQLLDRQPPISVYNTAGEKWDNFQGKID FVDCKFTYPSRPDSQVLNGLSVSISPGQTLAFVGSSGCGKSTSIQLLE RFYDPDQGKVMIDGHDSKKVNVQFLRSNIGIVSQEPVLFACSIMDNI KYGDNTKEIPMERVIAAAKQAQLHDFVMSLPEKYETNVGSQGSQLS RGEKQRIAIARAIVRDPKILLLDEATSALDTESEKTVQVALDKAREG RTCIVIAHRLSTIQNADIIAVMAQGVVIEKGTHEELMAQKGAYYKLV TTGSPIS 82 MDLEAAKNGTAWRPTSAEGDFELGISSKQKRKKTKTVKMIGVLTLF ABCB4 RYSDWQDKLFMSLGTIMAIAHGSGLPLMMIVFGEMTDKFVDTAGN FSFPVNFSLSLLNPGKILEEEMTRYAYYYSGLGAGVLVAAYIQVSFW TLAAGRQIRKIRQKFFHAILRQEIGWFDINDTTELNTRLTDDISKISEG IGDKVGMFFQAVATFFAGFIVGFIRGWKLTLVIMAISPILGLSAAVW AKILSAFSDKELAAYAKAGAVAEEALGAIRTVIAFGGQNKELERYQ KHLENAKEIGIKKAISANISMGIAFLLIYASYALAFWYGSTLVISKEY TIGNAMTVFFSILIGAFSVGQAAPCIDAFANARGAAYVIFDIIDNNPKI DSFSERGHKPDSIKGNLEFNDVHFSYPSRANVKILKGLNLKVQSGQT VALVGSSGCGKSTTVQLIQRLYDPDEGTINIDGQDIRNFNVNYLREII GVVSQEPVLFSTTIAENICYGRGNVTMDEIKKAVKEANAYEFIMKLP QKFDTLVGERGAQLSGGQKQRIAIARALVRNPKILLLDEATSALDTE SEAEVQAALDKAREGRTTIVIAHRLSTVRNADVIAGFEDGVIVEQGS HSELMKKEGVYFKLVNMQTSGSQIQSEEFELNDEKAATRMAPNGW KSRLFRHSTQKNLKNSQMCQKSLDVETDGLEANVPPVSFLKVLKLN KTEWPYFVVGTVCAIANGGLQPAFSVIFSEIIAIFGPGDDAVKQQKC NIFSLIFLFLGIISFFTFFLQGFTFGKAGEILTRRLRSMAFKAMLRQDM SWFDDHKNSTGALSTRLATDAAQVQGATGTRLALIAQNIANLGTGII ISFIYGWQLTLLLLAVVPIIAVSGIVEMKLLAGNAKRDKKELEAAGK IATEAIENIRTVVSLTQERKFESMYVEKLYGPYRNSVQKAHIYGITFS ISQAFMYFSYAGCFRFGAYLIVNGHMRFRDVILVFSAIVFGAVALGH ASSFAPDYAKAKLSAAHLFMLFERQPLIDSYSEEGLKPDKFEGNITF NEVVFNYPTRANVPVLQGLSLEVKKGQTLALVGSSGCGKSTVVQL LERFYDPLAGTVFVDFGFQLLDGQEAKKLNVQWLRAQLGIVSQEPI LFDCSIAENIAYGDNSRVVSQDEIVSAAKAANIHPFIETLPHKYETRV GDKGTQLSGGQKQRIAIARALIRQPQILLLDEATSALDTESEKVVQE ALDKAREGRTCIVIAHRLSTIQNADLIVVFQNGRVKEHGTHQQLLA QKGIYFSMVSVQAGTQNL 83 MPVRGDRGFPPRRELSGWLRAPGMEELIWEQYTVTLQKDSKRGFGI TJP2 AVSGGRDNPHFENGETSIVISDVLPGGPADGLLQENDRVVMVNGTP MEDVLHSFAVQQLRKSGKVAAIVVKRPRKVQVAALQASPPLDQDD RAFEVMDEFDGRSFRSGYSERSRLNSHGGRSRSWEDSPERGRPHER ARSRERDLSRDRSRGRSLERGLDQDHARTRDRSRGRSLERGLDHDF GPSRDRDRDRSRGRSIDQDYERAYHRAYDPDYERAYSPEYRRGAR HDARSRGPRSRSREHPHSRSPSPEPRGRPGPIGVLLMKSRANEEYGL RLGSQIFVKEMTRTGLATKDGNLHEGDIILKINGTVTENMSLTDARK LIEKSRGKLQLVVLRDSQQTLINIPSLNDSDSEIEDISEIESNRSFSPEE RRHQYSDYDYHSSSEKLKERPSSREDTPSRLSRMGATPTPFKSTGDI AGTVVPETNKEPRYQEDPPAPQPKAAPRTFLRPSPEDEAIYGPNTKM VRFKKGDSVGLRLAGGNDVGIFVAGIQEGTSAEQEGLQEGDQILKV NTQDFRGLVREDAVLYLLEIPKGEMVTILAQSRADVYRDILACGRG DSFFIRSHFECEKETPQSLAFTRGEVFRVVDTLYDGKLGNWLAVRIG NELEKGLIPNKSRAEQMASVQNAQRDNAGDRADFWRMRGQRSGV KKNLRKSREDLTAVVSVSTKFPAYERVLLREAGFKRPVVLFGPIADI AMEKLANELPDWFQTAKTEPKDAGSEKSTGVVRLNTVRQIIEQDKH ALLDVTPKAVDLLNYTQWFPIVIFFNPDSRQGVKTMRQRLNPTSNK SSRKLFDQANKLKKTCAHLFTATINLNSANDSWFGSLKDTIQHQQG EAVWVSEGKMEGMDDDPEDRMSYLTAMGADYLSCDSRLISDFEDT DGEGGAYTDNELDEPAEEPLVSSITRSSEPVQHEESIRKPSPEPRAQM RRAASSDQLRDNSPPPAFKPEPPKAKTQNKEESYDFSKSYEYKSNPS AVAGNETPGASTKGYPPPVAAKPTFGRSILKPSTPIPPQEGEEVGESS EEQDNAPKSVLGKVKIFEKMDHKARLQRMQELQEAQNARIEIAQK HPDIYAVPIKTHKPDPGTPQHTSSRPPEPQKAPSRPYQDTRGSYGSD AEEEEYRQQLSEHSKRGYYGQSARYRDTEL 84 MATATRLLGWRVASWRLRPPLAGFVSQRAHSLLPVDDAINGLSEE IVD QRQLRQTMAKFLQEHLAPKAQEIDRSNEFKNLREFWKQLGNLGVL GITAPVQYGGSGLGYLEHVLVMEEISRASGAVGLSYGAHSNLCINQ LVRNGNEAQKEKYLPKLISGEYIGALAMSEPNAGSDVVSMKLKAE KKGNHYILNGNKFWITNGPDADVLIVYAKTDLAAVPASRGITAFIVE KGMPGFSTSKKLDKLGMRGSNTCELIFEDCKIPAANILGHENKGVY VLMSGLDLERLVLAGGPLGLMQAVLDHTIPYLHVREAFGQKIGHFQ LMQGKMADMYTRLMACRQYVYNVAKACDEGHCTAKDCAGVILY SAECATQVALDGIQCFGGNGYINDFPMGRFLRDAKLYEIGAGTSEV RRLVIGRAFNADFH 85 MALRGVSVRLLSRGPGLHVLRTWVSSAAQTEKGGRTQSQLAKSSR GCDH PEFDWQDPLVLEEQLTTDEILIRDTFRTYCQERLMPRILLANRNEVF HREIISEMGELGVLGPTIKGYGCAGVSSVAYGLLARELERVDSGYRS AMSVQSSLVMHPIYAYGSEEQRQKYLPQLAKGELLGCFGLTEPNSG SDPSSMETRAHYNSSNKSYTLNGTKTWITNSPMADLFVVWARCED GCIRGFLLEKGMRGLSAPRIQGKFSLRASATGMIIMDGVEVPEENVL PGASSLGGPFGCLNNARYGIAWGVLGASEFCLHTARQYALDRMQF GVPLARNQLIQKKLADMLTEITLGLHACLQLGRLKDQDKAAPEMV SLLKRNNCGKALDIARQARDMLGGNGISDEYHVIRHAMNLEAVNT YEGTHDIHALILGRAITGIQAFTASK 86 MFRAAAPGQLRRAASLLRFQSTLVIAEHANDSLAPITLNTITAATRL ETFA GGEVSCLVAGTKCDKVAQDLCKVAGIAKVLVAQHDVYKGLLPEEL TPLILATQKQFNYTHICAGASAFGKNLLPRVAAKLEVAPISDHAIKSP DTFVRTIYAGNALCTVKCDEKVKVFSVRGTSFDAAATSGGSASSEK ASSTSPVEISEWLDQKLTKSDRPELTGAKVVVSGGRGLKSGENFKLL YDLADQLHAAVGASRAAVDAGFVPNDMQVGQTGKIVAPELYIAV GISGAIQHLAGMKDSKTIVAINKDPEAPIFQVADYGIVADLFKVVPE MTEILKKK 87 MAELRVLVAVKRVIDYAVKIRVKPDRTGVVTDGVKHSMNPFCEIA ETFB VEEAVRLKEKKLVKEVIAVSCGPAQCQETIRTALAMGADRGIHVEV PPAEAERLGPLQVARVLAKLAEKEKVDLVLLGKQAIDDDCNQTGQ MTAGFLDWPQGTFASQVTLEGDKLKVEREIDGGLETLRLKLPAVVT ADLRLNEPRYATLPNIMKAKKKKIEVIKPGDLGVDLTSKLSVISVED PPQRTAGVKVETTEDLVAKLKEIGRI 88 MLVPLAKLSCLAYQCFHALKIKKNYLPLCATRWSSTSTVPRITTHYT ETFDH IYPRDKDKRWEGVNMERFAEEADVVIVGAGPAGLSAAVRLKQLAV AHEKDIRVCLVEKAAQIGAHTLSGACLDPGAFKELFPDWKEKGAPL NTPVTEDRFGILTEKYRIPVPILPGLPMNNHGNYIVRLGHLVSWMGE QAEALGVEVYPGYAAAEVLFHDDGSVKGIATNDVGIQKDGAPKAT FERGLELHAKVTIFAEGCHGHLAKQLYKKFDLRANCEPQTYGIGLK ELWVIDEKNWKPGRVDHTVGWPLDRHTYGGSFLYHLNEGEPLVAL GLVVGLDYQNPYLSPFREFQRWKHHPSIRPTLEGGKRIAYGARALN EGGFQSIPKLTFPGGLLIGCSPGFMNVPKIKGTHTAMKSGILAAESIF NQLTSENLQSKTIGLHVTEYEDNLKNSWVWKELYSVRNIRPSCHGV LGVYGGMIYTGIFYWILRGMEPWTLKHKGSDFERLKPAKDCTPIEY PKPDGQISFDLLSSVALSGTNHEHDQPAHLTLRDDSIPVNRNLSIYDG PEQRFCPAGVYEFVPVEQGDGFRLQINAQNCVHCKTCDIKDPSQNIN WVVPEGGGGPAYNGM 89 MASESGKLWGGRFVGAVDPIMEKFNASIAYDRHLWEVDVQGSKA ASL YSRGLEKAGLLTKAEMDQILHGLDKVAEEWAQGTFKLNSNDEDIH TANERRLKELIGATAGKLHTGRSRNDQVVTDLRLWMRQTCSTLSG LLWELIRTMVDRAEAERDVLFPGYTHLQRAQPIRWSHWILSHAVAL TRDSERLLEVRKRINVLPLGSGAIAGNPLGVDRELLRAELNFGAITL NSMDATSERDFVAEFLFWASLCMTHLSRMAEDLILYCTKEFSFVQL SDAYSTGSSLMPQKKNPDSLELIRSKAGRVFGRCAGLLMTLKGLPS TYNKDLQEDKEAVFEVSDTMSAVLQVATGVISTLQIHQENMGQAL SPDMLATDLAYYLVRKGMPFRQAHEASGKAVFMAETKGVALNQL SLQELQTISPLFSGDVICVWDYGHSVEQYGALGGTARSSVDWQIRQ VRALLQAQQA 90 MVGGSVPVFDEIILSTARMNRVLSFHSVSGILVCQAGCVLEELSRYV D2HGDH EERDFIMPLDLGAKGSCHIGGNVATNAGGLRFLRYGSLHGTVLGLE VVLADGTVLDCLTSLRKDNTGYDLKQLFIGSEGTLGIITTVSILCPPK PRAVNVAFLGCPGFAEVLQTFSTCKGMLGEILSAFEFMDAVCMQLV GRHLHLASPVQESPFYVLIETSGSNAGHDAEKLGHFLEHALGSGLVT DGTMATDQRKVKMLWALRERITEALSRDGYVYKYDLSLPVERLYD IVTDLRARLGPHAKHVVGYGHLGDGNLHLNVTAEAFSPSLLAALEP HVYEWTAGQQGSVSAEHGVGFRKRDVLGYSKPPGALQLMQQLKA LLDPKGILNPYKTLPSQA 91 MAAMRKALPRRLVGLASLRAVSTSSMGTLPKRVKIVEVGPRDGLQ HMGCL NEKNIVSTPVKIKLIDMLSEAGLSVIETTSFVSPKWVPQMGDHTEVL KGIQKFPGINYPVLTPNLKGFEAAVAAGAKEVVIFGAASELFTKKNI NCSIEESFQRFDAILKAAQSANISVRGYVSCALGCPYEGKISPAKVAE VTKKFYSMGCYEISLGDTIGVGTPGIMKDMLSAVMQEVPLAALAV HCHDTYGQALANTLMALQMGVSVVDSSVAGLGGCPYAQGASGNL ATEDLVYMLEGLGIHTGVNLQKLLEAGNFICQALNRKTSSKVAQAT CKL 92 MAAASAVSVLLVAAERNRWHRLPSLLLPPRTWVWRQRTMKYTTA MCCC1 TGRNITKVLIANRGEIACRVMRTAKKLGVQTVAVYSEADRNSMHV DMADEAYSIGPAPSQQSYLSMEKIIQVAKTSAAQAIHPGCGFLSENM EFAELCKQEGIIFIGPPPSAIRDMGIKSTSKSIMAAAGVPVVEGYHGE DQSDQCLKEHARRIGYPVMIKAVRGGGGKGMRIVRSEQEFQEQLES ARREAKKSFNDDAMLIEKFVDTPRHVEVQVFGDHHGNAVYLFERD CSVQRRHQKIIEEAPAPGIKSEVRKKLGEAAVRAAKAVNYVGAGTV EFIMDSKHNFCFMEMNTRLQVEHPVTEMITGTDLVEWQLRIAAGEK IPLSQEEITLQGHAFEARIYAEDPSNNFMPVAGPLVHLSTPRADPSTR IETGVRQGDEVSVHYDPMIAKLVVWAADRQAALTKLRYSLRQYNI VGLHTNIDFLLNLSGHPEFEAGNVHTDFIPQHHKQLLLSRKAAAKES LCQAALGLILKEKAMTDTFTLQAHDQFSPFSSSSGRRLNISYTRNMT LKDGKNNVAIAVTYNHDGSYSMQIEDKTFQVLGNLYSEGDCTYLK CSVNGVASKAKLIILENTIYLFSKEGSIEIDIPVPKYLSSVSSQETQGG PLAPMTGTIEKVFVKAGDKVKAGDSLMVMIAMKMEHTIKSPKDGT VKKVFYREGAQANRHTPLVEFEEEESDKRESE 93 MWAVLRLALRPCARASPAGPRAYHGDSVASLGTQPDLGSALYQEN MCCC2 YKQMKALVNQLHERVEHIKLGGGEKARALHISRGKLLPRERIDNLI DPGSPFLELSQFAGYQLYDNEEVPGGGIITGIGRVSGVECMIIANDAT VKGGAYYPVTVKKQLRAQEIAMQNRLPCIYLVDSGGAYLPRQADV FPDRDHFGRTFYNQAIMSSKNIAQIAVVMGSCTAGGAYVPAMADE NIIVRKQGTIFLAGPPLVKAATGEEVSAEDLGGADLHCRKSGVSDH WALDDHHALHLTRKVVRNLNYQKKLDVTIEPSEEPLFPADELYGIV GANLKRSFDVREVIARIVDGSRFTEFKAFYGDTLVTGFARIFGYPVGI VGNNGVLFSESAKKGTHFVQLCCQRNIPLLFLQNITGFMVGREYEA EGIAKDGAKMVAAVACAQVPKITLIIGGSYGAGNYGMCGRAYSPR FLYIWPNARISVMGGEQAANVLATITKDQRAREGKQFSSADEAALK EPIIKKFEEEGNPYYSSARVWDDGIIDPADTRLVLGLSFSAALNAPIE KTDFGIFRM 94 MAVAGPAPGAGARPRLDLQFLQRFLQILKVLFPSWSSQNALMFLTL ABCD4 LCLTLLEQFVIYQVGLIPSQYYGVLGNKDLEGFKTLTFLAVMLIVLN STLKSFDQFTCNLLYVSWRKDLTEHLHRLYFRGRAYYTLNVLRDDI DNPDQRISQDVERFCRQLSSMASKLIISPFTLVYYTYQCFQSTGWLG PVSIFGYFILGTVVNKTLMGPIVMKLVHQEKLEGDFRFKHMQIRVN AEPAAFYRAGHVEHMRTDRRLQRLLQTQRELMSKELWLYIGINTFD YLGSILSYVVIAIPIFSGVYGDLSPAELSTLVSKNAFVCIYLISCFTQLI DLSTTLSDVAGYTHRIGQLRETLLDMSLKSQDCEILGESEWGLDTPP GWPAAEPADTAFLLERVSISAPSSDKPLIKDLSLKISEGQSLLITGNTG TGKTSLLRVLGGLWTSTRGSVQMLTDFGPHGVLFLPQKPFFTDGTL REQVIYPLKEVYPDSGSADDERILRFLELAGLSNLVARTEGLDQQVD WNWYDVLSPGEMQRLSFARLFYLQPKYAVLDEATSALTEEVESEL YRIGQQLGMTFISVGHRQSLEKFHSLVLKLCGGGRWELMRIKVE 95 MASAVSPANLPAVLLQPRWKRVVGWSGPVPRPRHGHRAVAIKELI HCFC1 VVFGGGNEGIVDELHVYNTATNQWFIPAVRGDIPPGCAAYGFVCDG TRLLVFGGMVEYGKYSNDLYELQASRWEWKRLKAKTPKNGPPPCP RLGHSFSLVGNKCYLFGGLANDSEDPKNNIPRYLNDLYILELRPGSG VVAWDIPITYGVLPPPRESHTAVVYTEKDNKKSKLVIYGGMSGCRL GDLWTLDIDTLTWNKPSLSGVAPLPRSLHSATTIGNKMYVFGGWVP LVMDDVKVATHEKEWKCTNTLACLNLDTMAWETILMDTLEDNIPR ARAGHCAVAINTRLYIWSGRDGYRKAWNNQVCCKDLWYLETEKP PPPARVQLVRANTNSLEVSWGAVATADSYLLQLQKYDIPATAATAT SPTPNPVPSVPANPPKSPAPAAAAPAVQPLTQVGITLLPQAAPAPPTT TTIQVLPTVPGSSISVPTAARTQGVPAVLKVTGPQATTGTPLVTMRP ASQAGKAPVTVTSLPAGVRMVVPTQSAQGTVIGSSPQMSGMAALA AAAAATQKIPPSSAPTVLSVPAGTTIVKTMAVTPGTTTLPATVKVAS SPVMVSNPATRMLKTAAAQVGTSVSSATNTSTRPIITVHKSGTVTV AQQAQVVTTVVGGVTKTITLVKSPISVPGGSALISNLGKVMSVVQT KPVQTSAVTGQASTGPVTQIIQTKGPLPAGTILKLVTSADGKPTTIITT TQASGAGTKPTILGISSVSPSTTKPGTTTIIKTIPMSAIITQAGATGVTS SPGIKSPITIITTKVMTSGTGAPAKIITAVPKIATGHGQQGVTQVVLK GAPGQPGTILRTVPMGGVRLVTPVTVSAVKPAVTTLVVKGTTGVTT LGTVTGTVSTSLAGAGGHSTSASLATPITTLGTIATLSSQVINPTAITV SAAQTTLTAAGGLTTPTITMQPVSQPTQVTLITAPSGVEAQPVHDLP VSILASPTTEQPTATVTIADSGQGDVQPGTVTLVCSNPPCETHETGTT NTATTTVVANLGGHPQPTQVQFVCDRQEAAASLVTSTVGQQNGSV VRVCSNPPCETHETGTTNTATTATSNMAGQHGCSNPPCETHETGTT NTATTAMSSVGANHQRDARRACAAGTPAVIRISVATGALEAAQGS KSQCQTRQTSATSTTMTVMATGAPCSAGPLLGPSMAREPGGRSPAF VQLAPLSSKVRLSSPSIKDLPAGRHSHAVSTAAMTRSSVGAGEPRM APVCESLQGGSPSTTVTVTALEALLCPSATVTQVCSNPPCETHETGT TNTATTSNAGSAQRVCSNPPCETHETGTTHTATTATSNGGTGQPEG GQQPPAGRPCETHQTTSTGTTMSVSVGALLPDATSSHRTVESGLEV AAAPSVTPQAGTALLAPFPTQRVCSNPPCETHETGTTHTATTVTSN MSSNQDPPPAASDQGEVESTQGDSVNITSSSAITTTVSSTLTRAVTTV TQSTPVPGPSVPPPEELQVSPGPRQQLPPRQLLQSASTALMGESAEV LSASQTPELPAAVDLSSTGEPSSGQESAGSAVVATVVVQPPPPTQSE VDQLSLPQELMAEAQAGTTTLMVTGLTPEELAVTAAAEAAAQAAA TEEAQALAIQAVLQAAQQAVMGTGEPMDTSEAAATVTQAELGHLS AEGQEGQATTIPIVLTQQELAALVQQQQLQEAQAQQQHHHLPTEAL APADSLNDPAIESNCLNELAGTVPSTVALLPSTATESLAPSNTFVAPQ PVVVASPAKLQAAATLTEVANGIESLGVKPDLPPPPSKAPMKKENQ WFDVGVIKGTNVMVTHYFLPPDDAVPSDDDLGTVPDYNQLKKQEL QPGTAYKFRVAGINACGRGPFSEISAFKTCLPGFPGAPCAIKISKSPD GAHLTWEPPSVTSGKIIEYSVYLAIQSSQAGGELKSSTPAQLAFMRV YCGPSPSCLVQSSSLSNAHIDYTTKPAIIFRIAARNEKGYGPATQVRW LQETSKDSSGTKPANKRPMSSPEMKSAPKKSKADGQ 96 MATSGAASAELVIGWCIFGLLLLAILAFCWIYVRKYQSRRESEVVST LMBRD1 ITAIFSLAIALITSALLPVDIFLVSYMKNQNGTFKDWANANVSRQIED TVLYGYYTLYSVILFCVFFWIPFVYFYYEEKDDDDTSKCTQIKTALK YTLGFVVICALLLLVGAFVPLNVPNNKNSTEWEKVKSLFEELGSSH GLAALSFSISSLTLIGMLAAITYTAYGMSALPLNLIKGTRSAAYERLE NTEDIEEVEQHIQTIKSKSKDGRPLPARDKRALKQFEERLRTLKKRE RHLEFIENSWWTKFCGALRPLKIVWGIFFILVALLFVISLFLSNLDKA LHSAGIDSGFIIFGANLSNPLNMLLPLLQTVFPLDYILITIIIMYFIFTSM AGIRNIGIWFFWIRLYKIRRGRTRPQALLFLCMILLLIVLHTSYMIYSL APQYVMYGSQNYLIETNITSDNHKGNSTLSVPKRCDADAPEDQCTV TRTYLFLHKFWFFSAAYYFGNWAFLGVFLIGLIVSCCKGKKSVIEGV DEDSDISDDEPSVYSA 97 MSAKSRTIGIIGAPFSKGQPRGGVEEGPTVLRKAGLLEKLKEQECDV ARG1 KDYGDLPFADIPNDSPFQIVKNPRSVGKASEQLAGKVAEVKKNGRIS LVLGGDHSLAIGSISGHARVHPDLGVIWVDAHTDINTPLTTTSGNLH GQPVSFLLKELKGKIPDVPGFSWVTPCISAKDIVYIGLRDVDPGEHYI LKTLGIKYFSMTEVDRLGIGKVMEETLSYLLGRKKRPIHLSFDVDGL DPSFTPATGTPVVGGLTYREGLYITEEIYKTGLLSGLDIMEVNPSLGK TPEEVTRTVNTAVAITLACFGLAREGNHKPIDYLNPPK 98 MKSNPAIQAAIDLTAGAAGGTACVLTGQPFDTMKVKMQTFPDLYR SLC25A15 GLTDCCLKTYSQVGFRGFYKGTSPALIANIAENSVLFMCYGFCQQV VRKVAGLDKQAKLSDLQNAAAGSFASAFAALVLCPTELVKCRLQT MYEMETSGKIAKSQNTVWSVIKSILRKDGPLGFYHGLSSTLLREVPG YFFFFGGYELSRSFFASGRSKDELGPVPLMLSGGVGGICLWLAVYPV DCIKSRIQVLSMSGKQAGFIRTFINVVKNEGITALYSGLKPTMIRAFP ANGALFLAYEYSRKLMMNQLEAY 99 MAAAKVALTKRADPAELRTIFLKYASIEKNGEFFMSPNDFVTRYLNI SLC25A13 FGESQPNPKTVELLSGVVDQTKDGLISFQEFVAFESVLCAPDALFMV AFQLFDKAGKGEVTFEDVKQVFGQTTIHQHIPFNWDSEFVQLHFGK ERKRHLTYAEFTQFLLEIQLEHAKQAFVQRDNARTGRVTAIDFRDI MVTIRPHVLTPFVEECLVAAAGGTTSHQVSFSYFNGFNSLLNNMELI RKIYSTLAGTRKDVEVTKEEFVLAAQKFGQVTPMEVDILFQLADLY EPRGRMTLADIERIAPLEEGTLPFNLAEAQRQKASGDSARPVLLQVA ESAYRFGLGSVAGAVGATAVYPIDLVKTRMQNQRSTGSFVGELMY KNSFDCFKKVLRYEGFFGLYRGLLPQLLGVAPEKAIKLTVNDFVRD KFMHKDGSVPLAAEILAGGCAGGSQVIFTNPLEIVKIRLQVAGEITT GPRVSALSVVRDLGFFGIYKGAKACFLRDIPFSAIYFPCYAHVKASF ANEDGQVSPGSLLLAGAIAGMPAASLVTPADVIKTRLQVAARAGQT TYSGVIDCFRKILREEGPKALWKGAGARVFRSSPQFGVTLLTYELLQ RWFYIDFGGVKPMGSEPVPKSRINLPAPNPDHVGGYKLAVATFAGI ENKFGLYLPLFKPSVSTSKAIGGGP 100 MQPQSVLHSGYFHPLLRAWQTATTTLNASNLIYPIFVTDVPDDIQPIT ALAD SLPGVARYGVKRLEEMLRPLVEEGLRCVLIFGVPSRVPKDERGSAA DSEESPAIEAIHLLRKTFPNLLVACDVCLCPYTSHGHCGLLSENGAF RAEESRQRLAEVALAYAKAGCQVVAPSDMMDGRVEAIKEALMAH GLGNRVSVMSYSAKFASCFYGPFRDAAKSSPAFGDRRCYQLPPGAR GLALRAVDRDVREGADMLMVKPGMPYLDIVREVKDKHPDLPLAV YHVSGEFAMLWHGAQAGAFDLKAAVLEAMTAFRRAGADIIITYYT PQLLQWLKEE 101 MALQLGRLSSGPCWLVARGGCGGPRAWSQCGGGGLRAWSQRSAA CPOX GRVCRPPGPAGTEQSRGLGHGSTSRGGPWVGTGLAAALAGLVGLA TAAFGHVQRAEMLPKTSGTRATSLGRPEEEEDELAHRCSSFMAPPV TDLGELRRRPGDMKTKMELLILETQAQVCQALAQVDGGANFSVDR WERKEGGGGISCVLQDGCVFEKAGVSISVVHGNLSEEAAKQMRSR GKVLKTKDGKLPFCAMGVSSVIHPKNPHAPTIHFNYRYFEVEEADG NKQWWFGGGCDLTPTYLNQEDAVHFHRTLKEACDQHGPDLYPKF KKWCDDYFFIAHRGERRGIGGIFFDDLDSPSKEEVFRFVQSCARAVV PSYIPLVKKHCDDSFTPQEKLWQQLRRGRYVEFNLLYDRGTKFGLF TPGSRIESILMSLPLTARWEYMHSPSENSKEAEILEVLRHPRDWVR 102 MSGNGNAAATAEENSPKMRVIRVGTRKSQLARIQTDSVVATLKAS HMBS YPGLQFEIIAMSTTGDKILDTALSKIGEKSLFTKELEHALEKNEVDLV VHSLKDLPTVLPPGFTIGAICKRENPHDAVVFHPKFVGKTLETLPEK SVVGTSSLRRAAQLQRKFPHLEFRSIRGNLNTRLRKLDEQQEFSAIIL ATAGLQRMGWHNRVGQILHPEECMYAVGQGALGVEVRAKDQDIL DLVGVLHDPETLLRCIAERAFLRHLEGGCSVPVAVHTAMKDGQLY LTGGVWSLDGSDSIQETMQATIHVPAQHEDGPEDDPQLVGITARNIP RGPQLAAQNLGISLANLLLSKGAKNILDVARQLNDAH 103 MGRTVVVLGGGISGLAASYHLSRAPCPPKVVLVESSERLGGWIRSV PPOX RGPNGAIFELGPRGIRPAGALGARTLLLVSELGLDSEVLPVRGDHPA AQNRFLYVGGALHALPTGLRGLLRPSPPFSKPLFWAGLRELTKPRG KEPDETVHSFAQRRLGPEVASLAMDSLCRGVFAGNSRELSIRSCFPS LFQAEQTHRSILLGLLLGAGRTPQPDSALIRQALAERWSQWSLRGG LEMLPQALETHLTSRGVSVLRGQPVCGLSLQAEGRWKVSLRDSSLE ADHVISAIPASVLSELLPAEAAPLARALSAITAVSVAVVNLQYQGAH LPVQGFGHLVPSSEDPGVLGIVYDSVAFPEQDGSPPGLRVTVMLGG SWLQTLEASGCVLSQELFQQRAQEAAATQLGLKEMPSHCLVHLHK NCIPQYTLGHWQKLESARQFLTAHRLPLTLAGASYEGVAVNDCIES GRQAAVSVLGTEPNS 104 MAHAHIQGGRRAKSRFVVCIMSGARSKLALFLCGCYVVALGAHTG BTD EESVADHHEAEYYVAAVYEHPSILSLNPLALISRQEALELMNQNLDI YEQQVMTAAQKDVQIIVFPEDGIHGFNFTRTSIYPFLDFMPSPQVVR WNPCLEPHRFNDTEVLQRLSCMAIRGDMFLVANLGTKEPCHSSDPR CPKDGRYQFNTNVVFSNNGTLVDRYRKHNLYFEAAFDVPLKVDLIT FDTPFAGRFGIFTCFDILFFDPAIRVLRDYKVKHVVYPTAWMNQLPL LAAIEIQKAFAVAFGINVLAANVHHPVLGMTGSGIHTPLESFWYHD MENPKSHLIIAQVAKNPVGLIGAENATGETDPSHSKFLKILSGDPYC EKDAQEVHCDEATKWNVNAPPTFHSEMMYDNFTLVPVWGKEGYL HVCSNGLCCYLLYERPTLSKELYALGVFDGLHTVHGTYYIQVCALV RCGGLGFDTCGQEITEATGIFEFHLWGNFSTSYIFPLFLTSGMTLEVP DQLGWENDHYFLRKSRLSSGLVTAALYGRLYERD 105 MEDRLHMDNGLVPQKIVSVHLQDSTLKEVKDQVSNKQAQILEPKP HLCS EPSLEIKPEQDGMEHVGRDDPKALGEEPKQRRGSASGSEPAGDSDR GGGPVEHYHLHLSSCHECLELENSTIESVKFASAENIPDLPYDYSSSL ESVADETSPEREGRRVNLTGKAPNILLYVGSDSQEALGRFHEVRSVL ADCVDIDSYILYHLLEDSALRDPWTDNCLLLVIATRESIPEDLYQKF MAYLSQGGKVLGLSSSFTFGGFQVTSKGALHKTVQNLVFSKADQSE VKLSVLSSGCRYQEGPVRLSPGRLQGHLENEDKDRMIVHVPFGTRG GEAVLCQVHLELPPSSNIVQTPEDFNLLKSSNFRRYEVLREILTTLGL SCDMKQVPALTPLYLLSAAEEIRDPLMQWLGKHVDSEGEIKSGQLS LRFVSSYVSEVEITPSCIPVVTNMEAFSSEHFNLEIYRQNLQTKQLGK VILFAEVTPTTMRLLDGLMFQTPQEMGLIVIAARQTEGKGRGGNVW LSPVGCALSTLLISIPLRSQLGQRIPFVQHLMSVAVVEAVRSIPEYQDI NLRVKWPNDIYYSDLMKIGGVLVNSTLMGETFYILIGCGFNVTNSN PTICINDLITEYNKQHKAELKPLRADYLIARVVTVLEKLIKEFQDKGP NSVLPLYYRYWVHSGQQVHLGSAEGPKVSIVGLDDSGFLQVHQEG GEVVTVHPDGNSFDMLRNLILPKRR 106 MLKFRTVHGGLRLLGIRRTSTAPAASPNVRRLEYKPIKKVMVANRG PC EIAIRVFRACTELGIRTVAIYSEQDTGQMHRQKADEAYLIGRGLAPV QAYLHIPDIIKVAKENNVDAVHPGYGFLSERADFAQACQDAGVRFI GPSPEVVRKMGDKVEARAIAIAAGVPVVPGTDAPITSLHEAHEFSNT YGFPIIFKAAYGGGGRGMRVVHSYEELEENYTRAYSEALAAFGNGA LFVEKFIEKPRHIEVQILGDQYGNILHLYERDCSIQRRHQKVVEIAPA AHLDPQLRTRLTSDSVKLAKQVGYENAGTVEFLVDRHGKHYFIEV NSRLQVEHTVTEEITDVDLVHAQIHVAEGRSLPDLGLRQENIRINGC AIQCRVTTEDPARSFQPDTGRIEVFRSGEGMGIRLDNASAFQGAVISP HYDSLLVKVIAHGKDHPTAATKMSRALAEFRVRGVKTNIAFLQNV LNNQQFLAGTVDTQFIDENPELFQLRPAQNRAQKLLHYLGHVMVN GPTTPIPVKASPSPTDPVVPAVPIGPPPAGFRDILLREGPEGFARAVRN HPGLLLMDTTFRDAHQSLLATRVRTHDLKKIAPYVAHNFSKLFSME NWGGATFDVAMRFLYECPWRRLQELRELIPNIPFQMLLRGANAVG YTNYPDNVVFKFCEVAKENGMDVFRVFDSLNYLPNMLLGMEAAG SAGGVVEAAISYTGDVADPSRTKYSLQYYMGLAEELVRAGTHILCI KDMAGLLKPTACTMLVSSLRDRFPDLPLHIHTHDTSGAGVAAMLA CAQAGADVVDVAADSMSGMTSQPSMGALVACTRGTPLDTEVPME RVFDYSEYWEGARGLYAAFDCTATMKSGNSDVYENEIPGGQYTNL HFQAHSMGLGSKFKEVKKAYVEANQMLGDLIKVTPSSKIVGDLAQ FMVQNGLSRAEAEAQAEELSFPRSVVEFLQGYIGVPHGGFPEPFRSK VLKDLPRVEGRPGASLPPLDLQALEKELVDRHGEEVTPEDVLSAAM YPDVFAHFKDFTATFGPLDSLNTRLFLQGPKIAEEFEVELERGKTLHI KALAVSDLNRAGQRQVFFELNGQLRSILVKDTQAMKEMHFHPKAL KDVKGQIGAPMPGKVIDIKVVAGAKVAKGQPLCVLSAMKMETVVT SPMEGTVRKVHVTKDMTLEGDDLILEIE 107 MVDSTEYEVASQPEVETSPLGDGASPGPEQVKLKKEISLLNGVCLIV SLC7A7 GNMIGSGIFVSPKGVLIYSASFGLSLVIWAVGGLFSVFGALCYAELG TTIKKSGASYAYILEAFGGFLAFIRLWTSLLIIEPTSQAIIAITFANYMV QPLFPSCFAPYAASRLLAAACICLLTFINCAYVKWGTLVQDIFTYAK VLALIAVIVAGIVRLGQGASTHFENSFEGSSFAVGDIALALYSALFSY SGWDTLNYVTEEIKNPERNLPLSIGISMPIVTIIYILTNVAYYTVLDM RDILASDAVAVTFADQIFGIFNWIIPLSVALSCFGGLNASIVAASRLFF VGSREGHLPDAICMIHVERFTPVPSLLFNGIMALIYLCVEDIFQLINY YSFSYWFFVGLSIVGQLYLRWKEPDRPRPLKLSVFFPIVFCLCTIFLV AVPLYSDTINSLIGIAIALSGLPFYFLIIRVPEHKRPLYLRRIVGSATRY LQVLCMSVAAEMDLEDGGEMPKQRDPKSN 108 MVPRLLLRAWPRGPAVGPGAPSRPLSAGSGPGQYLQRSIVPTMHYQ CPT2 DSLPRLPIPKLEDTIRRYLSAQKPLLNDGQFRKTEQFCKSFENGIGKE LHEQLVALDKQNKHTSYISGPWFDMYLSARDSVVLNFNPFMAFNP DPKSEYNDQLTRATNMTVSAIRFLKTLRAGLLEPEVFHLNPAKSDTI TFKRLIRFVPSSLSWYGAYLVNAYPLDMSQYFRLFNSTRLPKPSRDE LFTDDKARHLLVLRKGNFYIFDVLDQDGNIVSPSEIQAHLKYILSDSS PAPEFPLAYLTSENRDIWAELRQKLMSSGNEESLRKVDSAVFCLCLD DFPIKDLVHLSHNMLHGDGTNRWFDKSFNLIIAKDGSTAVHFEHSW GDGVAVLRFFNEVFKDSTQTPAVTPQSQPATTDSTVTVQKLNFELT DALKTGITAAKEKFDATMKTLTIDCVQFQRGGKEFLKKQKLSPDAV AQLAFQMAFLRQYGQTVATYESCSTAAFKHGRTETIRPASVYTKRC SEAFVREPSRHSAGELQQMMVECSKYHGQLTKEAAMGQGFDRHLF ALRHLAAAKGIILPELYLDPAYGQINHNVLSTSTLSSPAVNLGGFAP VVSDGFGVGYAVHDNWIGCNVSSYPGRNAREFLQCVEKALEDMFD ALEGKSIKS 109 MAAGFGRCCRVLRSISRFHWRSQHTKANRQREPGLGFSFEFTEQQK ACADM EFQATARKFAREEIIPVAAEYDKTGEYPVPLIRRAWELGLMNTHIPE NCGGLGLGTFDACLISEELAYGCTGVQTAIEGNSLGQMPIIIAGNDQ QKKKYLGRMTEEPLMCAYCVTEPGAGSDVAGIKTKAEKKGDEYII NGQKMWITNGGKANWYFLLARSDPDPKAPANKAFTGFIVEADTPG IQIGRKELNMGQRCSDTRGIVFEDVKVPKENVLIGDGAGFKVAMGA FDKTRPVVAAGAVGLAQRALDEATKYALERKTFGKLLVEHQAISF MLAEMAMKVELARMSYQRAAWEVDSGRRNTYYASIAKAFAGDIA NQLATDAVQILGGNGFNTEYPVEKLMRDAKIYQIYEGTSQIQRLIVA REHIDKYKN 110 MAAALLARASGPARRALCPRAWRQLHTIYQSVELPETHQMLLQTC ACADS RDFAEKELFPIAAQVDKEHLFPAAQVKKMGGLGLLAMDVPEELGG AGLDYLAYAIAMEEISRGCASTGVIMSVNNSLYLGPILKFGSKEQKQ AWVTPFTSGDKIGCFALSEPGNGSDAGAASTTARAEGDSWVLNGT KAWITNAWEASAAVVFASTDRALQNKGISAFLVPMPTPGLTLGKKE DKLGIRGSSTANLIFEDCRIPKDSILGEPGMGFKIAMQTLDMGRIGIA SQALGIAQTALDCAVNYAENRMAFGAPLTKLQVIQFKLADMALAL ESARLLTWRAAMLKDNKKPFIKEAAMAKLAASEAATAISHQAIQIL GGMGYVTEMPAERHYRDARITEIYEGTSEIQRLVIAGHLLRSYRS 111 MQAARMAASLGRQLLRLGGGSSRLTALLGQPRPGPARRPYAGGAA ACADVL QLALDKSDSHPSDALTRKKPAKAESKSFAVGMFKGQLTTDQVFPYP SVLNEEQTQFLKELVEPVSRFFEEVNDPAKNDALEMVEETTWQGLK ELGAFGLQVPSELGGVGLCNTQYARLVEIVGMHDLGVGITLGAHQS IGFKGILLFGTKAQKEKYLPKLASGETVAAFCLTEPSSGSDAASIRTS AVPSPCGKYYTLNGSKLWISNGGLADIFTVFAKTPVTDPATGAVKE KITAFVVERGFGGITHGPPEKKMGIKASNTAEVFFDGVRVPSENVLG EVGSGFKVAMHILNNGRFGMAAALAGTMRGIIAKAVDHATNRTQF GEKIHNFGLIQEKLARMVMLQYVTESMAYMVSANMDQGATDFQIE AAISKIFGSEAAWKVTDECIQIMGGMGFMKEPGVERVLRDLRIFRIF EGTNDILRLFVALQGCMDKGKELSGLGSALKNPFGNAGLLLGEAG KQLRRRAGLGSGLSLSGLVHPELSRSGELAVRALEQFATVVEAKLIK HKKGIVNEQFLLQRLADGAIDLYAMVVVLSRASRSLSEGHPTAQHE KMLCDTWCIEAAARIREGMAALQSDPWQQELYRNFKSISKALVER GGVVTSNPLGF 112 MGHSKQIRILLLNEMEKLEKTLFRLEQGYELQFRLGPTLQGKAVTV AGL YTNYPFPGETFNREKFRSLDWENPTEREDDSDKYCKLNLQQSGSFQ YYFLQGNEKSGGGYIVVDPILRVGADNHVLPLDCVTLQTFLAKCLG PFDEWESRLRVAKESGYNMIHFTPLQTLGLSRSCYSLANQLELNPDF SRPNRKYTWNDVGQLVEKLKKEWNVICITDVVYNHTAANSKWIQE HPECAYNLVNSPHLKPAWVLDRALWRFSCDVAEGKYKEKGIPALIE NDHHMNSIRKIIWEDIFPKLKLWEFFQVDVNKAVEQFRRLLTQENR RVTKSDPNQHLTIIQDPEYRRFGCTVDMNIALTTFIPHDKGPAAIEEC CNWFHKRMEELNSEKHRLINYHQEQAVNCLLGNVFYERLAGHGPK LGPVTRKHPLVTRYFTFPFEEIDFSMEESMIHLPNKACFLMAHNGW VMGDDPLRNFAEPGSEVYLRRELICWGDSVKLRYGNKPEDCPYLW AHMKKYTEITATYFQGVRLDNCHSTPLHVAEYMLDAARNLQPNLY VVAELFTGSEDLDNVFVTRLGISSLIREAMSAYNSHEEGRLVYRYG GEPVGSFVQPCLRPLMPAIAHALFMDITHDNECPIVHRSAYDALPST TIVSMACCASGSTRGYDELVPHQISVVSEERFYTKWNPEALPSNTGE VNFQSGIIAARCAISKLHQELGAKGFIQVYVDQVDEDIVAVTRHSPSI HQSVVAVSRTAFRNPKTSFYSKEVPQMCIPGKIEEVVLEARTIERNT KPYRKDENSINGTPDITVEIREHIQLNESKIVKQAGVATKGPNEYIQEI EFENLSPGSVIIFRVSLDPHAQVAVGILRNHLTQFSPHFKSGSLAVDN ADPILKIPFASLASRLTLAELNQILYRCESEEKEDGGGCYDIPNWSAL KYAGLQGLMSVLAEIRPKNDLGHPFCNNLRSGDWMIDYVSNRLISR SGTIAEVGKWLQAMFFYLKQIPRYLIPCYFDAILIGAYTTLLDTAWK QMSSFVQNGSTFVKHLSLGSVQLCGVGKFPSLPILSPALMDVPYRLN EITKEKEQCCVSLAAGLPHFSSGIFRCWGRDTFIALRGILLITGRYVE ARNIILAFAGTLRHGLIPNLLGEGIYARYNCRDAVWWWLQCIQDYC KMVPNGLDILKCPVSRMYPTDDSAPLPAGTLDQPLFEVIQEAMQKH MQGIQFRERNAGPQIDRNMKDEGFNITAGVDEETGFVYGGNRFNC GTWMDKMGESDRARNRGIPATPRDGSAVEIVGLSKSAVRWLLELS KKNIFPYHEVTVKRHGKAIKVSYDEWNRKIQDNFEKLFHVSEDPSD LNEKHPNLVHKRGIYKDSYGASSPWCDYQLRPNFTIAMVVAPELFT TEKAWKALEIAEKKLLGPLGMKTLDPDDMVYCGIYDNALDNDNY NLAKGFNYHQGPEWLWPIGYFLRAKLYFSRLMGPETTAKTIVLVKN VLSRHYVHLERSPWKGLPELTNENAQYCPFSCETQAWSIATILETLY DL 113 MEEGMNVLHDFGIQSTHYLQVNYQDSQDWFILVSVIADLRNAFYV G6PC LFPIWFHLQEAVGIKLLWVAVIGDWLNLVFKWILFGQRPYWWVLD TDYYSNTSVPLIKQFPVTCETGPGSPSGHAMGTAGVYYVMVTSTLSI FQGKIKPTYRFRCLNVILWLGFWAVQLNVCLSRIYLAAHFPHQVVA GVLSGIAVAETFSHIHSIYNASLKKYFLITFFLFSFAIGFYLLLKGLGV DLLWTLEKAQRWCEQPEWVHIDTTPFASLLKNLGTLFGLGLALNSS MYRESCKGKLSKWLPFRLSSIVASLVLLHVFDSLKPPSQVELVFYVL SFCKSAVVPLASVSVIPYCLAQVLGQPHKKSL 114 MAAPMTPAARPEDYEAALNAALADVPELARLLEIDPYLKPYAVDF GBE1 QRRYKQFSQILKNIGENEGGIDKFSRGYESFGVHRCADGGLYCKEW APGAEGVFLTGDFNGWNPFSYPYKKLDYGKWELYIPPKQNKSVLV PHGSKLKVVITSKSGEILYRISPWAKYVVREGDNVNYDWIHWDPEH SYEFKHSRPKKPRSLRIYESHVGISSHEGKVASYKHFTCNVLPRIKGL GYNCIQLMAIMEHAYYASFGYQITSFFAASSRYGTPEELQELVDTAH SMGIIVLLDVVHSHASKNSADGLNMFDGTDSCYFHSGPRGTHDLW DSRLFAYSSWEILRFLLSNIRWWLEEYRFDGFRFDGVTSMLYHHHG VGQGFSGDYSEYFGLQVDEDALTYLMLANHLVHTLCPDSITIAEDV SGMPALCSPISQGGGGFDYRLAMAIPDKWIQLLKEFKDEDWNMGDI VYTLTNRRYLEKCIAYAESHDQALVGDKSLAFWLMDAEMYTNMS VLTPFTPVIDRGIQLHKMIRLITHGLGGEGYLNFMGNEFGHPEWLDF PRKGNNESYHYARRQFHLTDDDLLRYKFLNNFDRDMNRLEERYG WLAAPQAYVSEKHEGNKIIAFERAGLLFIFNFHPSKSYTDYRVGTAL PGKFKIVLDSDAAEYGGHQRLDHSTDFFSEAFEHNGRPYSLLVYIPS RVALILQNVDLPN 115 MRSRSNSGVRLDGYARLVQQTILCHQNPVTGLLPASYDQKDAWVR PHKA1 DNVYSILAVWGLGLAYRKNADRDEDKAKAYELEQSVVKLMRGLL HCMIRQVDKVESFKYSQSTKDSLHAKYNTKTCATVVGDDQWGHL QLDATSVYLLFLAQMTASGLHIIHSLDEVNFIQNLVFYIEAAYKTAD FGIWERGDKTNQGISELNASSVGMAKAALEALDELDLFGVKGGPQS VIHVLADEVQHCQSILNSLLPRASTSKEVDASLLSVVSFPAFAVEDS QLVELTKQEIITKLQGRYGCCRFLRDGYKTPKEDPNRLYYEPAELKL FENIECEWPLFWTYFILDGVFSGNAEQVQEYKEALEAVLIKGKNGV PLLPELYSVPPDRVDEEYQNPHTVDRVPMGKLPHMWGQSLYILGSL MAEGFLAPGEIDPLNRRFSTVPKPDVVVQVSILAETEEIKTILKDKGI YVETIAEVYPIRVQPARILSHIYSSLGCNNRMKLSGRPYRHMGVLGT SKLYDIRKTIFTFTPQFIDQQQFYLALDNKMIVEMLRTDLSYLCSRW RMTGQPTITFPISHSMLDEDGTSLNSSILAALRKMQDGYFGGARVQT GKLSEFLTTSCCTHLSFMDPGPEGKLYSEDYDDNYDYLESGNWMN DYDSTSHARCGDEVARYLDHLLAHTAPHPKLAPTSQKGGLDRFQA AVQTTCDLMSLVTKAKELHVQNVHMYLPTKLFQASRPSFNLLDSP HPRQENQVPSVRVEIHLPRDQSGEVDFKALVLQLKETSSLQEQADIL YMLYTMKGPDWNTELYNERSATVRELLTELYGKVGEIRHWGLIRYI SGILRKKVEALDEACTDLLSHQKHLTVGLPPEPREKTISAPLPYEALT QLIDEASEGDMSISILTQEIMVYLAMYMRTQPGLFAEMFRLRIGLIIQ VMATELAHSLRCSAEEATEGLMNLSPSAMKNLLHHILSGKEFGVER SVRPTDSNVSPAISIHEIGAVGATKTERTGIMQLKSEIKQVEFRRLSIS AESQSPGTSMTPSSGSFPSAYDQQSSKDSRQGQWQRRRRLDGALNR VPVGFYQKVWKVLQKCHGLSVEGFVLPSSTTREMTPGEIKFSVHVE SVLNRVPQPEYRQLLVEAILVLTMLADIEIHSIGSIIAVEKIVHIANDL FLQEQKTLGADDTMLAKDPASGICTLLYDSAPSGRFGTMTYLSKAA ATYVQEFLPHSICAMQ 116 MRSRSNSGVRLDGYARLVQQTILCYQNPVTGLLSASHEQKDAWVR PHKA2 DNIYSILAVWGLGMAYRKNADRDEDKAKAYELEQNVVKLMRGLL QCMMRQVAKVEKFKHTQSTKDSLHAKYNTATCGTVVGDDQWGH LQVDATSLFLLFLAQMTASGLRIIFTLDEVAFIQNLVFYIEAAYKVA DYGMWERGDKTNQGIPELNASSVGMAKAALEAIDELDLFGAHGGR KSVIHVLPDEVEHCQSILFSMLPRASTSKEIDAGLLSIISFPAFAVEDV NLVNVTKNEIISKLQGRYGCCRFLRDGYKTPREDPNRLHYDPAELK LFENIECEWPVFWTYFIIDGVFSGDAVQVQEYREALEGILIRGKNGIR LVPELYAVPPNKVDEEYKNPHTVDRVPMGKVPHLWGQSLYILSSLL AEGFLAAGEIDPLNRRFSTSVKPDVVVQVTVLAENNHIKDLLRKHG VNVQSIADIHPIQVQPGRILSHIYAKLGRNKNMNLSGRPYRHIGVLG TSKLYVIRNQIFTFTPQFTDQHHFYLALDNEMIVEMLRIELAYLCTC WRMTGRPTLTFPISRTMLTNDGSDIHSAVLSTIRKLEDGYFGGARVK LGNLSEFLTTSFYTYLTFLDPDCDEKLFDNASEGTFSPDSDSDLVGY LEDTCNQESQDELDHYINHLLQSTSLRSYLPPLCKNTEDRHVFSAIH STRDILSVMAKAKGLEVPFVPMTLPTKVLSAHRKSLNLVDSPQPLLE KVPESDFQWPRDDHGDVDCEKLVEQLKDCSNLQDQADILYILYVIK GPSWDTNLSGQHGVTVQNLLGELYGKAGLNQEWGLIRYISGLLRK KVEVLAEACTDLLSHQKQLTVGLPPEPREKIISAPLPPEELTKLIYEA SGQDISIAVLTQEIVVYLAMYVRAQPSLFVEMLRLRIGLIIQVMATEL ARSLNCSGEEASESLMNLSPFDMKNLLHHILSGKEFGVERSVRPIHS STSSPTISIHEVGHTGVTKTERSGINRLRSEMKQMTRRFSADEQFFSV GQAASSSAHSSKSARSSTPSSPTGTSSSDSGGHHIGWGERQGQWLRR RRLDGAINRVPVGFYQRVWKILQKCHGLSIDGYVLPSSTTREMTPH EIKFAVHVESVLNRVPQPEYRQLLVEAIMVLTLLSDTEMTSIGGIIHV DQIVQMASQLFLQDQVSIGAMDTLEKDQATGICHFFYDSAPSGAYG TMTYLTRAVASYLQELLPNSGCQMQ 117 MAGAAGLTAEVSWKVLERRARTKRSGSVYEPLKSINLPRPDNETL PHKB WDKLDHYYRIVKSTLLLYQSPTTGLFPTKTCGGDQKAKIQDSLYCA AGAWALALAYRRIDDDKGRTHELEHSAIKCMRGILYCYMRQADKV QQFKQDPRPTTCLHSVFNVHTGDELLSYEEYGHLQINAVSLYLLYL VEMISSGLQIIYNTDEVSFIQNLVFCVERVYRVPDFGVWERGSKYNN GSTELHSSSVGLAKAALEAINGFNLFGNQGCSWSVIFVDLDAHNRN RQTLCSLLPRESRSHNTDAALLPCISYPAFALDDEVLFSQTLDKVVR KLKGKYGFKRFLRDGYRTSLEDPNRCYYKPAEIKLFDGIECEFPIFFL YMMIDGVFRGNPKQVQEYQDLLTPVLHHTTEGYPVVPKYYYVPAD FVEYEKNNPGSQKRFPSNCGRDGKLFLWGQALYIIAKLLADELISPK DIDPVQRYVPLKDQRNVSMRFSNQGPLENDLVVHVALIAESQRLQV FLNTYGIQTQTPQQVEPIQIWPQQELVKAYLQLGINEKLGLSGRPDR PIGCLGTSKIYRILGKTVVCYPIIFDLSDFYMSQDVFLLIDDIKNALQF IKQYWKMHGRPLFLVLIREDNIRGSRFNPILDMLAALKKGIIGGVKV HVDRLQTLISGAVVEQLDFLRISDTEELPEFKSFEELEPPKHSKVKRQ SSTPSAPELGQQPDVNISEWKDKPTHEILQKLNDCSCLASQAILLGIL LKREGPNFITKEGTVSDHIERVYRRAGSQKLWLAVRYGAAFTQKFS SSIAPHITTFLVHGKQVTLGAFGHEEEVISNPLSPRVIQNIIYYKCNTH DEREAVIQQELVIHIGWIISNNPELFSGMLKIRIGWIIHAMEYELQIRG GDKPALDLYQLSPSEVKQLLLDILQPQQNGRCWLNRRQIDGSLNRT PTGFYDRVWQILERTPNGIIVAGKHLPQQPTLSDMTMYEMNFSLLV EDTLGNIDQPQYRQIVVELLMVVSIVLERNPELEFQDKVDLDRLVKE AFNEFQKDQSRLKEIEKQDDMTSFYNTPPLGKRGTCSYLTKAVMNL LLEGEVKPNNDDPCLIS 118 MTLDVGPEDELPDWAAAKEFYQKYDPKDVIGRGVSSVVRRCVHRA PHKG2 TGHEFAVKIMEVTAERLSPEQLEEVREATRRETHILRQVAGHPHIITL IDSYESSSFMFLVFDLMRKGELFDYLTEKVALSEKETRSIMRSLLEA VSFLHANNIVHRDLKPENILLDDNMQIRLSDFGFSCHLEPGEKLREL CGTPGYLAPEILKCSMDETHPGYGKEVDLWACGVILFTLLAGSPPF WHRRQILMLRMIMEGQYQFSSPEWDDRSSTVKDLISRLLQVDPEAR LTAEQALQHPFFERCEGSQPWNLTPRQRFRVAVWTVLAAGRVALS THRVRPLTKNALLRDPYALRSVRHLIDNCAFRLYGHWVKKGEQQN RAALFQHRPPGPFPIMGPEEEGDSAAITEDEAVLVLG 119 MAAQGYGYYRTVIFSAMFGGYSLYYFNRKTFSFVMPSLVEEIPLDK SLC37A4 DDLGFITSSQSAAYAISKFVSGVLSDQMSARWLFSSGLLLVGLVNIF FAWSSTVPVFAALWFLNGLAQGLGWPPCGKVLRKWFEPSQFGTW WAILSTSMNLAGGLGPILATILAQSYSWRSTLALSGALCVVVSFLCL LLIHNEPADVGLRNLDPMPSEGKKGSLKEESTLQELLLSPYLWVLST GYLVVFGVKTCCTDWGQFFLIQEKGQSALVGSSYMSALEVGGLVG SIAAGYLSDRAMAKAGLSNYGNPRHGLLLFMMAGMTVSMYLFRV TVTSDSPKLWILVLGAVFGFSSYGPIALFGVIANESAPPNLCGTSHAI VGLMANVGGFLAGLPFSTIAKHYSWSTAFWVAEVICAASTAAFFLL RNIRTKMGRVSKKAE 120 MAAPGPALCLFDVDGTLTAPRQKITKEMDDFLQKLRQKIKIGVVGG PMM2 SDFEKVQEQLGNDVVEKYDYVFPENGLVAYKDGKLLCRQNIQSHL GEALIQDLINYCLSYIAKIKLPKKRGTFIEFRNGMLNVSPIGRSCSQEE RIEFYELDKKENIRQKFVADLRKEFAGKGLTFSIGGQISFDVFPDGW DKRYCLRHVENDGYKTIYFFGDKTMPGGNDHEIFTDPRTMGYSVT APEDTRRICELLFS 121 MPSETPQAEVGPTGCPHRSGPHSAKGSLEKGSPEDKEAKEPLWIRPD CBS APSRCTWQLGRPASESPHHHTAPAKSPKILPDILKKIGDTPMVRINKI GKKFGLKCELLAKCEFFNAGGSVKDRISLRMIEDAERDGTLKPGDTI IEPTSGNTGIGLALAAAVRGYRCIIVMPEKMSSEKVDVLRALGAEIV RTPTNARFDSPESHVGVAWRLKNEIPNSHILDQYRNASNPLAHYDT TADEILQQCDGKLDMLVASVGTGGTITGIARKLKEKCPGCRIIGVDP EGSILAEPEELNQTEQTTYEVEGIGYDFIPTVLDRTVVDKWFKSNDE EAFTFARMLIAQEGLLCGGSAGSTVAVAVKAAQELQEGQRCVVILP DSVRNYMTKFLSDRWMLQKGFLKEEDLTEKKPWWWHLRVQELGL SAPLTVLPTITCGHTIEILREKGFDQAPVVDEAGVILGMVTLGNMLS SLLAGKVQPSDQVGKVIYKQFKQIRLTDTLGRLSHILEMDHFALVV HEQIQYHSTGKSSQRQMVFGVVTAIDLLNFVAAQERDQK 122 MSFIPVAEDSDFPIHNLPYGVFSTRGDPRPRIGVAIGDQILDLSIIKHLF FAH TGPVLSKHQDVFNQPTLNSFMGLGQAAWKEARVFLQNLLSVSQAR LRDDTELRKCAFISQASATMHLPATIGDYTDFYSSRQHATNVGIMFR DKENALMPNWLHLPVGYHGRASSVVVSGTPIRRPMGQMKPDDSKP PVYGACKLLDMELEMAFFVGPGNRLGEPIPISKAHEHIFGMVLMND WSARDIQKWEYVPLGPFLGKSFGTTVSPWVVPMDALMPFAVPNPK QDPRPLPYLCHDEPYTFDINLSVNLKGEGMSQAATICKSNFKYMYW TMLQQLTHHSVNGCNLRPGDLLASGTISGPEPENFGSMLELSWKGT KPIDLGNGQTRKFLLDGDEVIITGYCQGDGYRIGFGQCAGKVLPALL PS 123 MDPYMIQMSSKGNLPSILDVHVNVGGRSSVPGKMKGRKARWSVRP TAT SDMAKKTFNPIRAIVDNMKVKPNPNKTMISLSIGDPTVFGNLPTDPE VTQAMKDALDSGKYNGYAPSIGFLSSREEIASYYHCPEAPLEAKDVI LTSGCSQAIDLCLAVLANPGQNILVPRPGFSLYKTLAESMGIEVKLY NLLPEKSWEIDLKQLEYLIDEKTACLIVNNPSNPCGSVFSKRHLQKIL AVAARQCVPILADEIYGDMVFSDCKYEPLATLSTDVPILSCGGLAKR WLVPGWRLGWILIHDRRDIFGNEIRDGLVKLSQRILGPCTIVQGALK SILCRTPGEFYHNTLSFLKSNADLCYGALAAIPGLRPVRPSGAMYLM VGIEMEHFPEFENDVEFTERLVAEQSVHCLPATCFEYPNFIRVVITVP EVMMLEACSRIQEFCEQHYHCAEGSQEECDK 124 MSRSGTDPQQRQQASEADAAAATFRANDHQHIRYNPLQDEWVLVS GALT AHRMKRPWQGQVEPQLLKTVPRHDPLNPLCPGAIRANGEVNPQYD STFLFDNDFPALQPDAPSPGPSDHPLFQAKSARGVCKVMCFHPWSD VTLPLMSVPEIRAVVDAWASVTEELGAQYPWVQIFENKGAMMGCS NPHPHCQVWASSFLPDIAQREERSQQAYKSQHGEPLLMEYSRQELL RKERLVLTSEHWLVLVPFWATWPYQTLLLPRRHVRRLPELTPAERD DLASIMKKLLTKYDNLFETSFPYSMGWHGAPTGSEAGANWNHWQ LHAHYYPPLLRSATVRKFMVGYEMLAQAQRDLTPEQAAERLRALP EVHYHLGQKDRETATIA 125 MAALRQPQVAELLAEARRAFREEFGAEPELAVSAPGRVNLIGEHTD GALK1 YNQGLVLPMALELMTVLVGSPRKDGLVSLLTTSEGADEPQRLQFPL PTAQRSLEPGTPRWANYVKGVIQYYPAAPLPGFSAVVVSSVPLGGG LSSSASLEVATYTFLQQLCPDSGTIAARAQVCQQAEHSFAGMPCGI MDQFISLMGQKGHALLIDCRSLETSLVPLSDPKLAVLITNSNVRHSL ASSEYPVRRRQCEEVARALGKESLREVQLEELEAARDLVSKEGFRR ARHVVGEIRRTAQAAAALRRGDYRAFGRLMVESHRSLRDDYEVSC PELDQLVEAALAVPGVYGSRMTGGGFGGCTVTLLEASAAPHAMRH IQEHYGGTATFYLSQAADGAKVLCL 126 MAEKVLVTGGAGYIGSHTVLELLEAGYLPVVIDNFHNAFRGGGSLP GALE ESLRRVQELTGRSVEFEEMDILDQGALQRLFKKYSFMAVIHFAGLK AVGESVQKPLDYYRVNLTGTIQLLEIMKAHGVKNLVFSSSATVYGN PQYLPLDEAHPTGGCTNPYGKSKFFIEEMIRDLCQADKTWNAVLLR YFNPTGAHASGCIGEDPQGIPNNLMPYVSQVAIGRREALNVFGNDY DTEDGTGVRDYIHVVDLAKGHIAALRKLKEQCGCRIYNLGTGTGYS VLQMVQAMEKASGKKIPYKVVARREGDVAACYANPSLAQEELGW TAALGLDRMCEDLWRWQKQNPSGFGTQA 127 MAEQVALSRTQVCGILREELFQGDAFHQSDTHIFIIMGASGDLAKKK G6PD IYPTIWWLFRDGLLPENTFIVGYARSRLTVADIRKQSEPFFKATPEEK LKLEDFFARNSYVAGQYDDAASYQRLNSHMNALHLGSQANRLFYL ALPPTVYEAVTKNIHESCMSQIGWNRIIVEKPFGRDLQSSDRLSNHIS SLFREDQIYRIDHYLGKEMVQNLMVLRFANRIFGPIWNRDNIACVIL TFKEPFGTEGRGGYFDEFGIIRDVMQNHLLQMLCLVAMEKPASTNS DDVRDEKVKVLKCISEVQANNVVLGQYVGNPDGEGEATKGYLDD PTVPRGSTTATFAAVVLYVENERWDGVPFILRCGKALNERKAEVRL QFHDVAGDIFHQQCKRNELVIRVQPNEAVYTKMMTKKPGMFFNPE ESELDLTYGNRYKNVKLPDAYERLILDVFCGSQMHFVRSDELREA WRIFTPLLHQIELEKPKPIPYIYGSRGPTEADELMKRVGFQYEGTYK WVNPHKL 128 MAEDKSKRDSIEMSMKGCQTNNGFVHNEDILEQTPDPGSSTDNLKH SLC3A1 STRGILGSQEPDFKGVQPYAGMPKEVLFQFSGQARYRIPREILFWLT VASVLVLIAATIAIIALSPKCLDWWQEGPMYQIYPRSFKDSNKDGNG DLKGIQDKLDYITALNIKTVWITSFYKSSLKDFRYGVEDFREVDPIFG TMEDFENLVAAIHDKGLKLIIDFIPNHTSDKHIWFQLSRTRTGKYTD YYIWHDCTHENGKTIPPNNWLSVYGNSSWHFDEVRNQCYFHQFMK EQPDLNFRNPDVQEEIKEILRFWLTKGVDGFSLDAVKFLLEAKHLR DEIQVNKTQIPDTVTQYSELYHDFTTTQVGMHDIVRSFRQTMDQYS TEPGRYRFMGTEAYAESIDRTVMYYGLPFIQEADFPFNNYLSMLDT VSGNSVYEVITSWMENMPEGKWPNWMIGGPDSSRLTSRLGNQYVN VMNMLLFTLPGTPITYYGEEIGMGNIVAANLNESYDINTLRSKSPMQ WDNSSNAGFSEASNTWLPTNSDYHTVNVDVQKTQPRSALKLYQDL SLLHANELLLNRGWFCHLRNDSHYVVYTRELDGIDRIFIVVLNFGES TLLNLHNMISGLPAKMRIRLSTNSADKGSKVDTSGIFLDKGEGLIFE HNTKNLLHRQTAFRDRCFVSNRACYSSVLNILYTSC 129 MGDTGLRKRREDEKSIQSQEPKTTSLQKELGLISGISIIVGTIIGSGIFV SLC7A9 SPKSVLSNTEAVGPCLIIWAACGVLATLGALCFAELGTMITKSGGEY PYLMEAYGPIPAYLFSWASLIVIKPTSFAIICLSFSEYVCAPFYVGCKP PQIVVKCLAAAAILFISTVNSLSVRLGSYVQNIFTAAKLVIVAIIIISGL VLLAQGNTKNFDNSFEGAQLSVGAISLAFYNGLWAYDGWNQLNYI TEELRNPYRNLPLAIIIGIPLVTACYILMNVSYFTVMTATELLQSQAV AVTFGDRVLYPASWIVPLFVAFSTIGAANGTCFTAGRLIYVAGREGH MLKVLSYISVRRLTPAPAIIFYGIIATIYIIPGDINSLVNYFSFAAWLFY GLTILGLIVMRFTRKELERPIKVPVVIPVLMTLISVFLVLAPIISKPTW EYLYCVLFILSGLLFYFLFVHYKFGWAQKISKPITMHLQMLMEVVPP EEDPE 130 MVNEARGNSSLNPCLEGSASSGSESSKDSSRCSTPGLDPERHERLRE MTHFR KMRRRLESGDKWFSLEFFPPRTAEGAVNLISRFDRMAAGGPLYIDV TWHPAGDPGSDKETSSMMIASTAVNYCGLETILHMTCCRQRLEEIT GHLHKAKQLGLKNIMALRGDPIGDQWEEEEGGFNYAVDLVKHIRS EFGDYFDICVAGYPKGHPEAGSFEADLKHLKEKVSAGADFIITQLFF EADTFFRFVKACTDMGITCPIVPGIFPIQGYHSLRQLVKLSKLEVPQE IKDVIEPIKDNDAAIRNYGIELAVSLCQELLASGLVPGLHFYTLNREM ATTEVLKRLGMWTEDPRRPLPWALSAHPKRREEDVRPIFWASRPKS YIYRTQEWDEFPNGRWGNSSSPAFGELKDYYLFYLKSKSPKEELLK MWGEELTSEESVFEVFVLYLSGEPNRNGHKVTCLPWNDEPLAAETS LLKEELLRVNRQGILTINSQPNINGKPSSDPIVGWGPSGGYVFQKAY LEFFTSRETAEALLQVLKKYELRVNYHLVNVKGENITNAPELQPNA VTWGIFPGREIIQPTVVDPVSFMFWKDEAFALWIERWGKLYEEESPS RTIIQYIHDNYFLVNLVDNDFPLDNCLWQVVEDTLELLNRPTQNAR ETEAP 131 MSPALQDLSQPEGLKKTLRDEINAILQKRIMVLDGGMGTMIQREKL MTR NEEHFRGQEFKDHARPLKGNNDILSITQPDVIYQIHKEYLLAGADIIE TNTFSSTSIAQADYGLEHLAYRMNMCSAGVARKAAEEVTLQTGIKR FVAGALGPTNKTLSVSPSVERPDYRNITFDELVEAYQEQAKGLLDG GVDILLIETIFDTANAKAALFALQNLFEEKYAPRPIFISGTIVDKSGRT LSGQTGEGFVISVSHGEPLCIGLNCALGAAEMRPFIEIIGKCTTAYVL CYPNAGLPNTFGDYDETPSMMAKHLKDFAMDGLVNIVGGCCGSTP DHIREIAEAVKNCKPRVPPATAFEGHMLLSGLEPFRIGPYTNFVNIGE RCNVAGSRKFAKLIMAGNYEEALCVAKVQVEMGAQVLDVNMDD GMLDGPSAMTRFCNLIASEPDIAKVPLCIDSSNFAVIEAGLKCCQGK CIVNSISLKEGEDDFLEKARKIKKYGAAMVVMAFDEEGQATETDTK IRVCTRAYHLLVKKLGFNPNDIIFDPNILTIGTGMEEHNLYAINFIHAT KVIKETLPGARISGGLSNLSFSFRGMEAIREAMHGVFLYHAIKSGMD MGIVNAGNLPVYDDIHKELLQLCEDLIWNKDPEATEKLLRYAQTQG TGGKKVIQTDEWRNGPVEERLEYALVKGIEKHIIEDTEEARLNQKK YPRPLNIIEGPLMNGMKIVGDLFGAGKMFLPQVIKSARVMKKAVGH LIPFMEKEREETRVLNGTVEEEDPYQGTIVLATVKGDVHDIGKNIVG VVLGCNNFRVIDLGVMTPCDKILKAALDHKADIIGLSGLITPSLDEMI FVAKEMERLAIRIPLLIGGATTSKTHTAVKIAPRYSAPVIHVLDASKS VVVCSQLLDENLKDEYFEEIMEEYEDIRQDHYESLKERRYLPLSQAR KSGFQMDWLSEPHPVKPTFIGTQVFEDYDLQKLVDYIDWKPFFDV WQLRGKYPNRGFPKIFNDKTVGGEARKVYDDAHNMLNTLISQKKL RARGVVGFWPAQSIQDDIHLYAEAAVPQAAEPIATFYGLRQQAEKD SASTEPYYCLSDFIAPLHSGIRDYLGLFAVACFGVEELSKAYEDDGD DYSSIMVKALGDRLAEAFAEELHERVRRELWAYCGSEQLDVADLR RLRYKGIRPAPGYPSQPDHTEKLTMWRLADIEQSTGIRLTESLAMAP ASAVSGLYFSNLKSKYFAVGKISKDQVEDYALRKNISVAEVEKWLG PILGYDTD 132 MGAASVRAGARLVEVALCSFTVTCLEVMRRFLLLYATQQGQAKAI MTRR AEEICEQAVVHGFSADLHCISESDKYDLKTETAPLVVVVSTTGTGDP PDTARKFVKEIQNQTLPVDFFAHLRYGLLGLGDSEYTYFCNGGKIID KRLQELGARHFYDTGHADDCVGLELVVEPWIAGLWPALRKHFRSS RGQEEISGALPVASPASSRTDLVKSELLHIESQVELLRFDDSGRKDSE VLKQNAVNSNQSNVVIEDFESSLTRSVPPLSQASLNIPGLPPEYLQVH LQESLGQEESQVSVTSADPVFQVPISKAVQLTTNDAIKTTLLVELDIS NTDFSYQPGDAFSVICPNSDSEVQSLLQRLQLEDKREHCVLLKIKAD TKKKGATLPQHIPAGCSLQFIFTWCLEIRAIPKKAFLRALVDYTSDSA EKRRLQELCSKQGAADYSRFVRDACACLLDLLLAFPSCQPPLSLLLE HLPKLQPRPYSCASSSLFHPGKLHFVFNIVEFLSTATTEVLRKGVCTG WLALLVASVLQPNIHASHEDSGKALAPKISISPRTTNSFHLPDDPSIPI IMVGPGTGIAPFIGFLQHREKLQEQHPDGNFGAMWLFFGCRHKDRD YLFRKELRHFLKHGILTHLKVSFSRDAPVGEEEAPAKYVQDNIQLH GQQVARILLQENGHIYVCGDAKNMAKDVHDALVQIISKEVGVEKL EAMKTLATLKEEKRYLQDIWS 133 MPEQERQITAREGASRKILSKLSLPTRAWEPAMKKSFAFDNVGYEG ATP7B GLDGLGPSSQVATSTVRILGMTCQSCVKSIEDRISNLKGIISMKVSLE QGSATVKYVPSVVCLQQVCHQIGDMGFEASIAEGKAASWPSRSLPA QEAVVKLRVEGMTCQSCVSSIEGKVRKLQGVVRVKVSLSNQEAVIT YQPYLIQPEDLRDHVNDMGFEAAIKSKVAPLSLGPIDIERLQSTNPK RPLSSANQNFNNSETLGHQGSHVVTLQLRIDGMHCKSCVLNIEENIG QLLGVQSIQVSLENKTAQVKYDPSCTSPVALQRAIEALPPGNFKVSL PDGAEGSGTDHRSSSSHSPGSPPRNQVQGTCSTTLIAIAGMTCASCV HSIEGMISQLEGVQQISVSLAEGTATVLYNPSVISPEELRAAIEDMGF EASVVSESCSTNPLGNHSAGNSMVQTTDGTPTSVQEVAPHTGRLPA NHAPDILAKSPQSTRAVAPQKCFLQIKGMTCASCVSNIERNLQKEAG VLSVLVALMAGKAEIKYDPEVIQPLEIAQFIQDLGFEAAVMEDYAG SDGNIELTITGMTCASCVHNIESKLTRTNGITYASVALATSKALVKF DPEIIGPRDIIKIIEEIGFHASLAQRNPNAHHLDHKMEIKQWKKSFLCS LVFGIPVMALMIYMLIPSNEPHQSMVLDHNIIPGLSILNLIFFILCTFV QLLGGWYFYVQAYKSLRHRSANMDVLIVLATSIAYVYSLVILVVA VAEKAERSPVTFFDTPPMLFVFIALGRWLEHLAKSKTSEALAKLMS LQATEATVVTLGEDNLIIREEQVPMELVQRGDIVKVVPGGKFPVDG KVLEGNTMADESLITGEAMPVTKKPGSTVIAGSINAHGSVLIKATHV GNDTTLAQIVKLVEEAQMSKAPIQQLADRFSGYFVPFIIIMSTLTLVV WIVIGFIDFGVVQRYFPNPNKHISQTEVIIRFAFQTSITVLCIACPCSLG LATPTAVMVGTGVAAQNGILIKGGKPLEMAHKIKTVMFDKTGTITH GVPRVMRVLLLGDVATLPLRKVLAVVGTAEASSEHPLGVAVTKYC KEELGTETLGYCTDFQAVPGCGIGCKVSNVEGILAHSERPLSAPASH LNEAGSLPAEKDAVPQTFSVLIGNREWLRRNGLTISSDVSDAMTDH EMKGQTAILVAIDGVLCGMIAIADAVKQEAALAVHTLQSMGVDVV LITGDNRKTARAIATQVGINKVFAEVLPSHKVAKVQELQNKGKKVA MVGDGVNDSPALAQADMGVAIGTGTDVAIEAADVVLIRNDLLDVV ASIHLSKRTVRRIRINLVLALIYNLVGIPIAAGVFMPIGIVLQPWMGS AAMAASSVSVVLSSLQLKCYKKPDLERYEAQAHGHMKPLTASQVS VHIGMDDRWRDSPRATPWDQVSYVSQVSLSSLTSDKPSRHSAAAD DDGDKWSLLLNGRDEEQYI 134 MATRSPGVVISDDEPGYDLDLFCIPNHYAEDLERVFIPHGLIMDRTE HPRT1 RLARDVMKEMGGHHIVALCVLKGGYKFFADLLDYIKALNRNSDRS IPMTVDFIRLKSYCNDQSTGDIKVIGGDDLSTLTGKNVLIVEDIIDTG KTMQTLLSLVRQYNPKMVKVASLLVKRTPRSVGYKPDFVGFEIPDK FVVGYALDYNEYFRDLNHVCVISETGKAKYKA 135 MGEPGQSPSPRSSHGSPPTLSTLTLLLLLCGHAHSQCKILRCNAEYVS HJV STLSLRGGGSSGALRGGGGGGRGGGVGSGGLCRALRSYALCTRRT ARTCRGDLAFHSAVHGIEDLMIQHNCSRQGPTAPPPPRGPALPGAGS GLPAPDPCDYEGRFSRLHGRPPGFLHCASFGDPHVRSFHHHFHTCR VQGAWPLLDNDFLFVQATSSPMALGANATATRKLTIIFKNMQECID QKVYQAEVDNLPVAFEDGSINGGDRPGGSSLSIQTANPGNHVEIQA AYIGTTIIIRQTAGQLSFSIKVAEDVAMAFSAEQDLQLCVGGCPPSQR LSRSERNRRGAITIDTARRLCKEGLPVEDAYFHSCVFDVLISGDPNFT VAAQAALEDARAFLPDLEKLHLFPSDAGVPLSSATLLAPLLSGLFVL WLCIQ 136 MALSSQIWAACLLLLLLLASLTSGSVFPQQTGQLAELQPQDRAGAR HAMP ASWMPMFQRRRRRDTHFPICIFCCGCCHRSKCGMCCKT 137 MRSPRTRGRSGRPLSLLLALLCALRAKVCGASGQFELEILSMQNVN JAG1 GELQNGNCCGGARNPGDRKCTRDECDTYFKVCLKEYQSRVTAGGP CSFGSGSTPVIGGNTFNLKASRGNDRNRIVLPFSFAWPRSYTLLVEA WDSSNDTVQPDSIIEKASHSGMINPSRQWQTLKQNTGVAHFEYQIR VTCDDYYYGFGCNKFCRPRDDFFGHYACDQNGNKTCMEGWMGPE CNRAICRQGCSPKHGSCKLPGDCRCQYGWQGLYCDKCIPHPGCVH GICNEPWQCLCETNWGGQLCDKDLNYCGTHQPCLNGGTCSNTGPD KYQCSCPEGYSGPNCEIAEHACLSDPCHNRGSCKETSLGFECECSPG WTGPTCSTNIDDCSPNNCSHGGTCQDLVNGFKCVCPPQWTGKTCQ LDANECEAKPCVNAKSCKNLIASYYCDCLPGWMGQNCDININDCL GQCQNDASCRDLVNGYRCICPPGYAGDHCERDIDECASNPCLNGG HCQNEINRFQCLCPTGFSGNLCQLDIDYCEPNPCQNGAQCYNRASD YFCKCPEDYEGKNCSHLKDHCRTTPCEVIDSCTVAMASNDTPEGVR YISSNVCGPHGKCKSQSGGKFTCDCNKGFTGTYCHENINDCESNPC RNGGTCIDGVNSYKCICSDGWEGAYCETNINDCSQNPCHNGGTCRD LVNDFYCDCKNGWKGKTCHSRDSQCDEATCNNGGTCYDEGDAFK CMCPGGWEGTTCNIARNSSCLPNPCHNGGTCVVNGESFTCVCKEG WEGPICAQNTNDCSPHPCYNSGTCVDGDNWYRCECAPGFAGPDCR ININECQSSPCAFGATCVDEINGYRCVCPPGHSGAKCQEVSGRPCIT MGSVIPDGAKWDDDCNTCQCLNGRIACSKVWCGPRPCLLHKGHSE CPSGQSCIPILDDQCFVHPCTGVGECRSSSLQPVKTKCTSDSYYQDN CANITFTFNKEMMSPGLTTEHICSELRNLNILKNVSAEYSIYIACEPSP SANNEIHVAISAEDIRDDGNPIKEITDKIIDLVSKRDGNSSLIAAVAEV RVQRRPLKNRTDFLVPLLSSVLTVAWICCLVTAFYWCLRKRRKPGS HTHSASEDNTTNNVREQLNQIKNPIEKHGANTVPIKDYENKNSKMS KIRTHNSEVEEDDMDKHQQKARFAKQPAYTLVDREEKPPNGTPTK HPNWTNKQDNRDLESAQSLNRMEYIV 138 MASHRLLLLCLAGLVFVSEAGPTGTGESKCPLMVKVLDAVRGSPAI TTR NVAVHVFRKAADDTWEPFASGKTSESGELHGLTTEEEFVEGIYKVE IDTKSYWKALGISPFHEHAEVVFTANDSGPRRYTIAALLSPYSYSTT AVVTNPKE 139 MASHKLLVTPPKALLKPLSIPNQLLLGPGPSNLPPRIMAAGGLQMIG AGXT SMSKDMYQIMDEIKEGIQYVFQTRNPLTLVISGSGHCALEAALVNV LEPGDSFLVGANGIWGQRAVDIGERIGARVHPMTKDPGGHYTLQEV EEGLAQHKPVLLFLTHGESSTGVLQPLDGFGELCHRYKCLLLVDSV ASLGGTPLYMDRQGIDILYSGSQKALNAPPGTSLISFSDKAKKKMYS RKTKPFSFYLDIKWLANFWGCDDQPRMYHHTIPVISLYSLRESLALI AEQGLENSWRQHREAAAYLHGRLQALGLQLFVKDPALRLPTVTTV AVPAGYDWRDIVSYVIDHFDIEIMGGLGPSTGKVLRIGLLGCNATRE NVDRVTEALRAALQHCPKKKL 140 MKMRFLGLVVCLVLWTLHSEGSGGKLTAVDPETNMNVSEIISYWG LIPA FPSEEYLVETEDGYILCLNRIPHGRKNHSDKGPKPVVFLQHGLLADS SNWVTNLANSSLGFILADAGFDVWMGNSRGNTWSRKHKTLSVSQD EFWAFSYDEMAKYDLPASINFILNKTGQEQVYYVGHSQGTTIGFIAF SQIPELAKRIKMFFALGPVASVAFCTSPMAKLGRLPDHLIKDLFGDK EFLPQSAFLKWLGTHVCTHVILKELCGNLCFLLCGFNERNLNMSRV DVYTTHSPAGTSVQNMLHWSQAVKFQKFQAFDWGSSAKNYFHYN QSYPPTYNVKDMLVPTAVWSGGHDWLADVYDVNILLTQITNLVFH ESIPEWEHLDFIWGLDAPWRLYNKIINLMRKYQ 141 MASRLTLLTLLLLLLAGDRASSNPNATSSSSQDPESLQDRGEGKVAT SERPING1 TVISKMLFVEPILEVSSLPTTNSTTNSATKITANTTDEPTTQPTTEPTT QPTIQPTQPTTQLPTDSPTQPTTGSFCPGPVTLCSDLESHSTEAVLGD ALVDFSLKLYHAFSAMKKVETNMAFSPFSIASLLTQVLLGAGENTK TNLESILSYPKDFTCVHQALKGFTTKGVTSVSQIFHSPDLAIRDTFVN ASRTLYSSSPRVLSNNSDANLELINTWVAKNTNNKISRLLDSLPSDT RLVLLNAIYLSAKWKTTFDPKKTRMEPFHFKNSVIKVPMMNSKKYP VAHFIDQTLKAKVGQLQLSHNLSLVILVPQNLKHRLEDMEQALSPS VFKAIMEKLEMSKFQPTLLTLPRIKVTTSQDMLSIMEKLEFFDFSYD LNLCGLTEDPDLQVSAMQHQTVLELTETGVEAAAASAISVARTLLV FEVQQPFLFVLWDQQHKFPVFMGRVYDPRA 142 MGSPLRFDGRVVLVTGAGAGLGRAYALAFAERGALVVVNDLGGD HSD17B4 FKGVGKGSLAADKVVEEIRRRGGKAVANYDSVEEGEKVVKTALDA FGRIDVVVNNAGILRDRSFARISDEDWDIIHRVHLRGSFQVTRAAWE HMKKQKYGRIIMTSSASGIYGNFGQANYSAAKLGLLGLANSLAIEG RKSNIHCNTIAPNAGSRMTQTVMPEDLVEALKPEYVAPLVLWLCHE SCEENGGLFEVGAGWIGKLRWERTLGAIVRQKNHPMTPEAVKANW KKICDFENASKPQSIQESTGSIIEVLSKIDSEGGVSANHTSRATSTATS GFAGAIGQKLPPFSYAYTELEAIMYALGVGASIKDPKDLKFIYEGSS DFSCLPTFGVIIGQKSMMGGGLAEIPGLSINFAKVLHGEQYLELYKP LPRAGKLKCEAVVADVLDKGSGVVIIMDVYSYSEKELICHNQFSLF LVGSGGFGGKRTSDKVKVAVAIPNRPPDAVLTDTTSLNQAALYRLS GDWNPLHIDPNFASLAGFDKPILHGLCTFGFSARRVLQQFADNDVS RFKAIKARFAKPVYPGQTLQTEMWKEGNRIHFQTKVQETGDIVISN AYVDLAPTSGTSAKTPSEGGKLQSTFVFEEIGRRLKDIGPEVVKKVN AVFEWHITKGGNIGAKWTIDLKSGSGKVYQGPAKGAADTTIILSDE DFMEVVLGKLDPQKAFFSGRLKARGNIMLSQKLQMILKDYAKL 143 MEANGLGPQGFPELKNDTFLRAAWGEETDYTPVWCMRQAGRYLP UROD EFRETRAAQDFFSTCRSPEACCELTLQPLRRFPLDAAIIFSDILVVPQA LGMEVTMVPGKGPSFPEPLREEQDLERLRDPEVVASELGYVFQAITL TRQRLAGRVPLIGFAGAPWTLMTYMVEGGGSSTMAQAKRWLYQR PQASHQLLRILTDALVPYLVGQVVAGAQALQLFESHAGHLGPQLFN KFALPYIRDVAKQVKARLREAGLAPVPMIIFAKDGHFALEELAQAG YEVVGLDWTVAPKKARECVGKTVTLQGNLDPCALYASEEEIGQLV KQMLDDFGPHRYIANLGHGLYPDMDPEHVGAFVDAVHKHSRLLR QN 144 MGPRARPALLLLMLLQTAVLQGRLLRSHSLHYLFMGASEQDLGLSL HFE FEALGYVDDQLFVFYDHESRRVEPRTPWVSSRISSQMWLQLSQSLK GWDHMFTVDFWTIMENHNHSKESHTLQVILGCEMQEDNSTEGYW KYGYDGQDHLEFCPDTLDWRAAEPRAWPTKLEWERHKIRARQNR AYLERDCPAQLQQLLELGRGVLDQQVPPLVKVTHHVTSSVTTLRCR ALNYYPQNITMKWLKDKQPMDAKEFEPKDVLPNGDGTYQGWITL AVPPGEEQRYTCQVEHPGLDQPLIVIWEPSPSGTLVIGVISGIAVFVVI LFIGILFIILRKRQGSRGAMGHYVLAERE 145 MESKALLVLTLAVWLQSLTASRGGVAAADQRRDFIDIESKFALRTP LPL EDTAEDTCHLIPGVAESVATCHFNHSSKTFMVIHGWTVTGMYESW VPKLVAALYKREPDSNVIVVDWLSRAQEHYPVSAGYTKLVGQDVA RFINWMEEEFNYPLDNVHLLGYSLGAHAAGIAGSLTNKKVNRITGL DPAGPNFEYAEAPSRLSPDDADFVDVLHTFTRGSPGRSIGIQKPVGH VDIYPNGGTFQPGCNIGEAIRVIAERGLGDVDQLVKCSHERSIHLFID SLLNEENPSKAYRCSSKEAFEKGLCLSCRKNRCNNLGYEINKVRAK RSSKMYLKTRSQMPYKVFHYQVKIHFSGTESETHTNQAFEISLYGT VAESENIPFTLPEVSTNKTYSFLIYTEVDIGELLMLKLKWKSDSYFS WSDWWSSPGFAIQKIRVKAGETQKKVIFCSREKVSHLQKGKAPAVF VKCHDKSLNKKSG 146 MRPVRLMKVFVTRRIPAEGRVALARAADCEVEQWDSDEPIPAKELE GRHPR RGVAGAHGLLCLLSDHVDKRILDAAGANLKVISTMSVGIDHLALDE IKKRGIRVGYTPDVLTDTTAELAVSLLLTTCRRLPEAIEEVKNGGWT SWKPLWLCGYGLTQSTVGIIGLGRIGQAIARRLKPFGVQRFLYTGRQ PRPEEAAEFQAEFVSTPELAAQSDFIVVACSLTPATEGLCNKDFFQK MKETAVFINISRGDVVNQDDLYQALASGKIAAAGLDVTSPEPLPTN HPLLTLKNCVILPHIGSATHRTRNTMSLLAANNLLAGLRGEPMPSEL KL 147 MLGPQVWSSVRQGLSRSLSRNVGVWASGEGKKVDIAGIYPPVTTPF HOGA1 TATAEVDYGKLEENLHKLGTFPFRGFVVQGSNGEFPFLTSSERLEVV SRVRQAMPKNRLLLAGSGCESTQATVEMTVSMAQVGADAAMVVT PCYYRGRMSSAALIHHYTKVADLSPIPVVLYSVPANTGLDLPVDAV VTLSQHPNIVGMKDSGGDVTRIGLIVHKTRKQDFQVLAGSAGFLMA SYALGAVGGVCALANVLGAQVCQLERLCCTGQWEDAQKLQHRLIE PNAAVTRRFGIPGLKKIMDWFGYYGGPCRAPLQELSPAEEEALRMD FTSNGWL 148 MGPWGWKLRWTVALLLAAAGTAVGDRCERNEFQCQDGKCISYK LDLR WVCDGSAECQDGSDESQETCLSVTCKSGDFSCGGRVNRCIPQFWRC DGQVDCDNGSDEQGCPPKTCSQDEFRCHDGKCISRQFVCDSDRDCL DGSDEASCPVLTCGPASFQCNSSTCIPQLWACDNDPDCEDGSDEWP QRCRGLYVFQGDSSPCSAFEFHCLSGECIHSSWRCDGGPDCKDKSD EENCAVATCRPDEFQCSDGNCIHGSRQCDREYDCKDMSDEVGCVN VTLCEGPNKFKCHSGECITLDKVCNMARDCRDWSDEPIKECGTNEC LDNNGGCSHVCNDLKIGYECLCPDGFQLVAQRRCEDIDECQDPDTC SQLCVNLEGGYKCQCEEGFQLDPHTKACKAVGSIAYLFFTNRHEVR KMTLDRSEYTSLIPNLRNVVALDTEVASNRIYWSDLSQRMICSTQLD RAHGVSSYDTVISRDIQAPDGLAVDWIHSNIYWTDSVLGTVSVADT KGVKRKTLFRENGSKPRAIVVDPVHGFMYWTDWGTPAKIKKGGLN GVDIYSLVTENIQWPNGITLDLLSGRLYWVDSKLHSISSIDVNGGNR KTILEDEKRLAHPFSLAVFEDKVFWTDIINEAIFSANRLTGSDVNLLA ENLLSPEDMVLFHNLTQPRGVNWCERTTLSNGGCQYLCLPAPQINP HSPKFTCACPDGMLLARDMRSCLTEAEAAVATQETSTVRLKVSSTA VRTQHTTTRPVPDTSRLPGATPGLTTVEIVTMSHQALGDVAGRGNE KKPSSVRALSIVLPIVLLVFLCLGVFLLWKNWRLKNINSINFDNPVY QKTTEDEVHICHNQDGYSYPSRQMVSLEDDVA 149 MLWSGCRRFGARLGCLPGGLRVLVQTGHRS ACAD8 LTSCIDPSMGLNEEQKEFQKVAFDFAAREM APNMAEWDQKELFPVDVMRKAAQLGFGGVY IQTDVGGSGLSRLDTSVIFEALATGCTSTT AYISIHNMCAWMIDSFGNEE QRHKFCPPLCTMEKFASYCLTEPGSGSDAA SLLTSAKKQGDHYILNGSKAFISGAGESDI YVVMCRTGGPGPKGISCIVVEKGTPGLSFG KKEKKVGWNSQPTRAVIFEDCAVPVANRIG SEGQGFLIAVRGLNGGRINIASCSLGAAHA SVILTRDHLNVRKQFGEPLASNQYLQFTLADMATRLVAARLMVRN AAVALQEERKDAVALCSMAKLFATDECFAICNQALQMHGGYGYL KDYAVQQYVRDSRVHQILEGSNEVMRILISRSLLQE 150 MEGLAVRLLRGSRLLRRNFLTCLSSWKIPPHVSKSSQSEALLNITNN ACADSB GIHFAPLQTFTDEEMMIKSSVKKFAQEQIAPLVSTMDENSKMEKSVI QGLFQQGLMGIEVDPEYGGTGASFLSTVLVIEELAKVDASVAVFCEI QNTLINTLIRKHGTEEQKATYLPQLTTEKVGSFCLSEAGAGSDSFAL KTRADKEGDYYVLNGSKMWISSAEHAGLFLVMANVDPTIGYKGIT SFLVDRDTPGLHIGKPENKLGLRASSTCPLTFENVKVPEANILGQIGH GYKYAIGSLNEGRIGIAAQMLGLAQGCFDYTIPYIKERIQFGKRLFDF QGLQHQVAHVATQLEAARLLTYNAARLLEAGKPFIKEASMAKYYA SEIAGQTTSKCIEWMGGVGYTKDYPVEKYFRDAKIGTIYEGASNIQL NTIAKHIDAEY 151 MAVLAALLRSGARSRSPLLRRLVQEIRYVERSYVSKPTLKEVVIVSA ACAT1 TRTPIGSFLGSLSLLPATKLGSIAIQGAIEKAGIPKEEVKEAYMGNVL QGGEGQAPTRQAVLGAGLPISTPCTTINKVCASGMKAIMMASQSLM CGHQDVMVAGGMESMSNVPYVMNRGSTPYGGVKLEDLIVKDGLT DVYNKIHMGSCAENTAKKLNIARNEQDAYAINSYTRSKAAWEAGK FGNEVIPVTVTVKGQPDVVVKEDEEYKRVDFSKVPKLKTVFQKEN GTVTAANASTLNDGAAALVLMTADAAKRLNVTPLARIVAFADAAV EPIDFPIAPVYAASMVLKDVGLKKEDIAMWEVNEAFSLVVLANIKM LEIDPQKVNINGGAVSLGHPIGMSGARIVGHLTHALKQGEYGLASIC NGGGGASAMLIQKL 152 MLPHVVLTFRRLGCALASCRLAPARHRGSGLLHTAPVARSDRSAPV ACSF3 FTRALAFGDRIALDQHGRHTYRELYSRSLRLSQEICRLCGCVGGDLR EERVSFLCANDASYVVAQWASWMSGGVAVPLYRKHPAAQLEYVI CDSQSSVVLASQEYLELLSPVVRKLGVPLLPLTPAIYTGAVEEPAEV PVPEQGWRNKGAMIIYTSGTTGRPKGVLSTHQNIRAVVTGLVHKW AWTKDDVILHVLPLHHVHGVVNALLCPLWVGATCVMMPEFSPQQ VWEKFLSSETPRINVFMAVPTIYTKLMEYYDRHFTQPHAQDFLRAV CEEKIRLMVSGSAALPLPVLEKWKNITGHTLLERYGMTEIGMALSG PLTTAVRLPGSVGTPLPGVQVRIVSENPQREACSYTIHAEGDERGTK VTPGFEEKEGELLVRGPSVFREYWNKPEETKSAFTLDGWFKTGDTV VFKDGQYWIRGRTSVDIIKTGGYKVSALEVEWHLLAHPSITDVAVIG VPDMTWGQRVTAVVTLREGHSLSHRELKEWARNVLAPYAVPSELV LVEEIPRNQMGKIDKKALIRHFHPS 153 MTSCHIAEEHIQKVAIFGGTHGNELTGVFLVKHWLENGAEIQRTGLE ASPA VKPFITNPRAVKKCTRYIDCDLNRIFDLENLGKKMSEDLPYEVRRAQ EINHLFGPKDSEDSYDIIFDLHNTTSNMGCTLILEDSRNNFLIQMFHYI KTSLAPLPCYVYLIEHPSLKYATTRSIAKYPVGIEVGPQPQGVLRADI LDQMRKMIKHALDFIHHFNEGKEFPPCAIEVYKIIEKVDYPRDENGE IA AIIHPNLQDQDWKPLHPGDPMFLTLDGKTIPLGGDCTVYPVFVNEA AYYEKKEAFAKTTKLTLNAKSIRCCLH 154 MAAAVAAAPGALGSLHAGGARLVAACSAWLCPGLRLPGSLAGRR AUH AGPAIWAQGWVPAAGGPAPKRGYSSEMKTEDELRVRHLEEENRGI VVLGINRAYGKNSLSKNLIKMLSKAVDALKSDKKVRTIIIRSEVPGIF CAGADLKERAKMSSSEVGPFVSKIRAVINDIANLPVPTIAAIDGLAL GGGLELALACDIRVAASSAKMGLVETKLAIIPGGGGTQRLPRAIGMS LAKELIFSARVLDGKEAKAVGLISHVLEQNQEGDAAYRKALDLARE FLPQGPVAMRVAKLAINQGMEVDLVTGLAIEEACYAQTIPTKDRLE GLLAFKEKRPPRYKGE 155 MASTVVAVGLTIAAAGFAGRYVLQAMKHMEPQVKQVFQSLPKSAF DNAJC19 SGGYYRGGFEPKMTKREAALILGVSPTANKGKIRDAHRRIMLLNHP DKGGSPYIAAKINEAKDLLEGQAKK 156 MAEAVLRVARRQLSQRGGSGAPILLRQMFEPVSCTFTYLLGDRESR ETHE1 EAVLIDPVLETAPRDAQLIKELGLRLLYAVNTHCHADHITGSGLLRS LLPGCQSVISRLSGAQADLHIEDGDSIRFGRFALETRASPGHTPGCVT FVLNDHSMAFTGDALLIRGCGRTDFQQGCAKTLYHSVHEKIFTLPG DCLIYPAHDYHGFTVSTVEEERTLNPRLTLSCEEFVKIMGNLNLPKP QQIDFAVPANMRCGVQTPTA 157 MADQAPFDTDVNTLTRFVMEEGRKARGTGELTQLLNSLCTAVKAIS FBP1 SAVRKAGIAHLYGIAGSTNVTGDQVKKLDVLSNDLVMNMLKSSFA TCVLVSEEDKHAIIVEPEKRGKYVVCFDPLDGSSNIDCLVSVGTIFGI YRKKSTDEPSEKDALQPGRNLVAAGYALYGSATMLVLAMDCGVN CFMLDPAIGEFILVDKDVKIKKKGKIYSLNEGYARDFDPAVTEYIQR KKFPPDNSAPYGARYVGSMVADVHRTLVYGGIFLYPANKKSPNGK LRLLYECNPMAYVMEKAGGMATTGKEAVLDVIPTDIHQRAPVILGS PDDVLEFLKVYEKHSAQ 158 MSQLVECVPNFSEGKNQEVIDAISGAITQTPGCVLLDVDAGPSTNRT FTCD VYTFVGPPECVVEGALNAARVASRLIDMSRHQGEHPRMGALDVCP FIPVRGVSVDECVLCAQAFGQRLAEELDVPVYLYGEAARMDSRRTL PAIRAGEYEALPKKLQQADWAPDFGPSSFVPSWGATATGARKFLIA FNINLLGTKEQAHRIALNLREQGRGKDQPGRLKKVQGIGWYLDEKN LAQVSTNLLDFEVTALHTVYEETCREAQELSLPVVGSQLVGLVPLK ALLDAAAFYCEKENLFILEEEQRI RLVVSRLGLDSLCPFSPKERIIEYLVPERGPERGLGSKSLRAFVGEVG ARSAAPGGGSVAAAAAAMGAALGSMVGLMTYGRRQFQSLDTTMR RLIPPFREASAKLTTLVDADAEAFTAYLEAMRLPKNTPEEKDRRTA ALQEGLRRAVSVPLTLAETVASLWPALQELARCGNLACRSDLQVA AKALEMGVFGAYFNVLINLRDITDEAFKDQIHHRVSSLLQEAKTQA ALVLDCLETRQE 159 MATNWGSLLQDKQQLEELARQAVDRALAEGVLLRTSQEPTSSEVV GSS SYAPFTLFPSLVPSALLEQAYAVQMDFNLLVDAVSQNAAFLEQTLS STIKQDDFTARLFDIHKQVLKEGIAQTVFLGLNRSDYMFQRSADGSP ALKQIEINTISASFGGLASRTPAVHRHVLSVLSKTKEAGKILSNNPSK GLALGIAKAWELYGSPNALVLLIAQEKERNIFDQRAIENELLARNIH VIRRTFEDISEKGSLDQDRRLFVDGQEIAVVYFRDGYMPRQYSLQN WEARLLLERSHAAKCPDIATQLAGTKKVQQELSRPGMLEMLLPGQ PEAVARLRATFAGLYSLDVGEEGDQAIAEALAAPSRFVLKPQREGG GNNLYGEEMVQALKQLKDSEERASYILMEKIEPEPFENCLLRPGSPA RVVQCISELGIFGVYVRQEKTLVMNKHVGHLLRTKAIEHADGGVA AGVAVLDNPYPV 160 MGQREMWRLMSRFNAFKRTNTILHHLRMSKHTDAAEEVLLEKKG HIBCH CTGVITLNRPKFLNALTLNMIRQIYPQLKKWEQDPETFLIIIKGAGGK AFCAGGDIRVISEAEKAKQKIAPVFFREEYMLNNAVGSCQKPYVALI HGITMGGGVGLSVHGQFRVATEKCLFAMPETAIGLFPDVGGGYFLP RLQGKLGYFLALTGFRLKGRDVYRAGIATHFVDSEKLAMLEEDLLA LKSPSKENIASVLENYHTESKIDRDKSFILEEHMDKINSCFSANTVEEI IENLQQDGSSFALEQLKVINKMSPTSLKITLRQLMEGSSKTLQEVLT MEYRLSQACMRGHDFHEGVRAVLIDKDQSPKWKPADLKEVTEEDL NNHFKSLGSSDLKF 161 MAGYLRVVRSLCRASGSRPAWAPAALTAPTSQEQPRRHYADKRIK IDH2 VAKPVVEMDGDEMTRIIWQFIKEKLILPHVDIQLKYFDLGLPNRDQT DDQVTIDSALATQKYSVAVKCATITPDEARVEEFKLKKMWKSPNG TIRNILGGTVFREPIICKNIPRLVPGWTKPITIGRHAHGDQYKATDFV ADRAGTFKMVFTPKDGSGVKEWEVYNFPAGGVGMGMYNTDESIS GFAHSCFQYAIQKKWPLYMSTKNTILKAYDGRFKDIFQEIFDKHYK TDFDKNKIWYEHRLIDDMVAQVLKSSGGFVWACKNYDGDVQSDIL AQGFGSLGLMTSVLVCPDGKTIEAEAAHGTVTRHYREHQKGRPTST NPIASIFAWTRGLEHRGKLDGNQDLIRFAQMLEKVCVETVESGAMT KDLAGCIHGLSNVKLNEHFLNTTDFLDTIKSNLDRALGRQ 162 MVPALRYLVGACGRARGLFAGGSPGACGFASGRPRPLCGGSRSAST L2HGDH SSFDIVIVGGGIVGLASARALILRHPSLSIGVLEKEKDLAVHQTGHNS GVIHSGIYYKPESLKAKLCVQGAALLYEYCQQKGISYKQCGKLIVA VEQEEIPRLQALYEKGLQNGVPGLRLIQQEDIKKKEPYCRGLMAIDC PHTGIVDYRQVALSFAQDFQEAGGSVLTNFEVKGIEMAKESPSRSID GMQYPIVIKNTKGEEIRCQYVVTCAGLYSDRISELSGCTPDPRIVPFR GDYLLLKPEKCYLVKGNIYPVPDSRFPFLGVHFTPRMDGSIWLGPN AVLAFKREGYRPFDFSATDVMDIIINSGLIKLASQNFSYGVTEMYKA CFLGATVKYLQKFIPEITISDILRGPAGVRAQALDRDGNLVEDFVFD AGVGDIGNRILHVRNAPSPAATSSIAISGMIADEVQQRFEL 163 MRGFGPGLTARRLLPLRLPPRPPGPRLASGQAAGALERAMDELLRR MLYCD AVPPTPAYELREKTPAPAEGQCADFVSFYGGLAETAQRAELLGRLA RGFGVDHGQVAEQSAGVLHLRQQQREAAVLLQAEDRLRYALVPR YRGLFHHISKLDGGVRFLVQLRADLLEAQALKLVEGPDVREMNGV LKGMLSEWFSSGFLNLERVTWHSPCEVLQKISEAEAVHPVKNWMD MKRRVGPYRRCYFFSHCSTPGEPLVVLHVALTGDISSNIQAIVKEHP PSETEEKNKITAAIFYSISLTQQGLQG VELGTFLIKRVVKELQREFPHLGVFSSLSPIPGFTKWLLGLLNSQTKE HGRNELFTDSECKEISEITGGPINETLKLLLSSSEWVQSEKLVRALQT PLMRLCAWYLYGEKHRGYALNPVANFHLQNGAVLWRINWMADV SLRGITGSCGLMANYRYFLEETGPNSTSYLGSKIIKASEQVLSLVAQF QKNSKL 164 MVVGAFPMAKLLYLGIRQVSKPLANRIKEAARRSEFFKTYICLPPAQ OPA3 LYHWVEMRTKMRIMGFRGTVIKPLNEEAAAELGAELLGEATIFIVG GGCLVLEYWRHQAQQRHKEEEQRAAWNALRDEVGHLALALEALQ AQVQAAPPQGALEELRTELQEVRAQLCNPGRSASHAVPASKK 165 MGSPEGRFHFAIDRGGTFTDVFAQCPGGHVRVLKLLSEDPANYADA OPLAH PTEGIRRILEQEAGMLLPRDQPLDSSHIASIRMGTTVATNALLERKGE RVALLVTRGFRDLLHIGTQARGDLFDLAVPMPEVLYEEVLEVDERV VLHRGEAGTGTPVKGRTGDLLEVQQPVDLGALRGKLEGLLSRGIRS LAVVLMHSYTWAQHEQQVGVLARELGFTHVSLSSEAMPMVRIVPR GHTACADAYLTPAIQRYVQGFCRGFQGQLKDVQVLFMRSDGGLAP MDTFSGSSAVLSGPAGGVVGYSATTYQQEGGQPVIGFDMGGTSTD VSRYAGEFEHVFEASTAGVTLQAPQLDINTVAAGGGSRLFFRSGLF VVGPESAGAHPGPACYRKGGPVTVTDANLVLGRLLPASFPCIFGPG ENQPLSPEASRKALEAVATEVNSFLTNGPCPASPLSLEEVAMGFVRV ANEAMCRPIRALTQARGHDPSAHVLACFGGAGGQHACAIARALGM DTVHIHRHSGLLSALGLALADVVHEAQEPCSLLYAPETFVQLDQRL SRLEEQCVDALQAQGFPRSQISTESFLHLRYQGTDCALMVSAHQHP ATA RSPRAGDFGAAFVERYMREFGFVIPERPVVVDDVRVRGTGRSGLRL EDAPKAQTGPPRVDKMTQCYFEGGYQETPVYLLAELGYGHKLHGP CLIIDSNSTILVEPGCQAEVTKTGDICISVGAEVPGTVGPQLDPIQLSIF SHRFMSIAEQMGRILQRTAISTNIKERLDFSCALFGPDGGLVSNAPHI PVHLGAMQETVQFQIQHLGADLHPGDVLLSNHPSAGGSHLPDLTVI TPVFWPGQTRPVFYVASRGHHADIGGITPGSMPPHSTMLQQEGAVF LSFKLVQGGVFQEEAVTEALRAPGKVPNCSGTRNLHDNLSDLRAQ VAANQKGIQLVGELIGQYGLDVVQAYMGHIQANAELAVRDMLRAF GTSRQARGLPLEVSSEDHMDDGSPIRLRVQISLSQGSAVFDFSGTGP EVFGNLNAPRAVTLSALIYCLRCLVGRDIPLNQGCLAPVRVVIPRGSI LDPSPEAAVVGGNVLTSQRVVDVILGAFGACAASQGCMNNVTLGN AHMGYYETVAGGAGAGPSWHGRSGVHSHMTNTRITDPEILESRYP VILRRFELRRGSGGRGRFRGGDGVTRELLFREEALLSVLTERRAFRP YGLHGGEPGARGLNLLIRKNGRTVNLGGKTSVTVYPGDVFCLHTPG GGGYGDPEDPAPPPGSPPQALAFPEHGSVYEYRRAQEAV 166 MAALKLLSSGLRLCASARGSGATWYKGCVCSFSTSAHRHTKFYTD OXCT1 PVEAVKDIPDGATVLVGGFGLCGIPENLIDALLKTGVKGLTAVSNN AGVDNFGLGLLLRSKQIKRMVSSYVGENAEFERQYLSGELEVELTP QGTLAERIRAGGAGVPAFYTPTGYGTLVQEGGSPIKYNKDGSVAIA SKPREVREFNGQHFILEEAITGDFALVKAWKADRAGNVIFRKSARN FNLPMCKAAETTVVEVEEIVDIGAFAPEDIHIPQIYVHRLIKGEKYEK RIERLSIRKEGDGEAKSAKPGDDVRERIIKRAALEFEDGMYANLGIGI PLLASNFISPNITVHLQSENGVLGLGPYPRQHEADADLINAGKETVTI LPGASFFSSDESFAMIRGGHVDLTMLGAMQVSKYGDLANWMIPGK MVKGMGGAMDLVSSAKTKVVVTMEHSAKGNAHKIMEKCTLPLTG KQCVNRIITEKAVFDVDKKKGLTLIELWEGLTVDDVQKSTGCDFAV SPKLMPMQQIAN 167 MSRLLWRKVAGATVGPGPVPAPGRWVSSSVPASDPSDGQRRRQQQ POLG QQQQQQQQQQPQQPQVLSSEGGQLRHNPLDIQMLSRGLHEQIFGQG GEMPGEAAVRRSVEHLQKHGLWGQPAVPLPDVELRLPPLYGDNLD QHFRLLAQKQSLPYLEAANLLLQAQLPPKPPAWAWAEGWTRYGPE GEAVPVAIPEERALVFDVEVCLAEGTCPTLAVAISPSAWYSWCSQR LVEERYSWTSQLSPADLIPLEVPTGASSPTQRDWQEQLVVGHNVSF DRAHIREQYLIQGSRMRFLDTMSMHMAISGLSSFQRSLWIAAKQGK HKVQPPTKQGQKSQRKARRGPAISSWDWLDISSVNSLAEVHRLYV GGPPLEKEPRELFVKGTMKDIRENFQDLMQYCAQDVWATHEVFQQ QLPLFLERCPHPVTLAGMLEMGVSYLPVNQNWERYLAEAQGTYEE LQREMKKSLMDLANDACQLLSGERYKEDPWLWDLEWDLQEFKQK KAKKVKKEPATASKLPIEGAGAPGDPMDQEDLGPCSEEEEFQQDV MARACLQKLKGTTELLPKRPQHLPGHPGWYRKLCPRLDDPAWTPG PSLLSLQMRVTPKLMALTWDGFPLHYSERHGWGYLVPGRRDNLAK LPTGTTLESAGVVCPYRAIESLYRKHCLEQGKQQLMPQEAGLAEEF LLTDNSAIWQTVEELDYLEVEAEAKMENLRAAVPGQPLALTARGG PKDTQPSYHHGNGPYNDVDIPGCWFFKLPHKDGNSCNVGSPFAKDF LPKMEDGTLQAGPGGASGPRALEINKMISFWRNAHKRISSQMVVW LPRSALPRAVIRHPDYDEEGLYGAILPQVVTAGTITRRAVEPTWLTA SNARPDRVGSELKAMVQAPPGYTLVGADVDSQELWIAAVLGDAHF AGMHGCTAFGWMTLQGRKSRGTDLHSKTATTVGISREHAKIFNYG RIYGAGQPFAERLLMQFNHRLTQQEAAEKAQQMYAATKGLRWYR LSDEGEWLVRELNLPVDRTEGGWISLQDLRKVQRETARKSQWKKW EVVAERAWKGGTESEMFNKLESIATSDIPRTPVLGCCISRALEPSAV QEEFMTSRVNWVVQSSAVDYLHLMLVAMKWLFEEFAIDGRFCISIH DEVRYLVREEDRYRAALALQITNLLTRCMFAYKLGLNDLPQSVAFF SAVDIDRCLRKEVTMDCKTPSNPTGMERRYGIPQGEALDIYQIIELT KGSLEKRSQPGP 168 MSTAALITLVRSGGNQVRRRVLLSSRLLQDDRRVTPTCHSSTSEPRC PPM1K SRFDPDGSGSPATWDNFGIWDNRIDEPILLPPSIKYGKPIPKISLENVG CASQIGKRKENEDRFDFAQLTDEVLYFAVYDGHGGPAAADFCHTH MEKCIMDLLPKEKNLETLLTLAFLEIDKAFSSHARLSADATLLTSGT TATVALLRDGIELVVASVGDSRAILCRKGKPMKLTIDHTPERKDEKE RIKKCGGFVAWNSLGQPHVNGRLAMTRSIGDLDLKTSGVIAEPETK RIKLHHADDSFLVLTTDGINFMVNSQEICDFVNQCHDPNEAAHAVT EQAIQYGTEDNSTAVVVPFGAWGKYKNSEINFSFSRSFASSGRWA 169 MSLAAYCVICCRRIGTSTSPPKSGTHWRDIRNIIKFTGSLILGGSLFLT SERAC1 YEVLALKKAVTLDTQVVEREKMKSYIYVHTVSLDKGENHGIAWQA RKELHKAVRKVLATSAKILRNPFADPFSTVDIEDHECAVWLLLRKS KSDDKTTRLEAVREMSETHHWHDYQYRIIAQACDPKTLIGLARSEE SDLRFFLLPPPLPSLKEDSSTEEELRQLLASLPQTELDECIQYFTSLAL SESSQ SLAAQKGGLWCFGGNGLPYAESFGEVPSATVEMFCLEAIVKHSEIST HCDKIEANGGLQLLQRLYRLHKDCPKVQRNIMRVIGNMALNEHLH SSIVRSGWVSIMAEAMKSPHIMESSHAARILANLDRETVQEKYQDG VYVLHPQYRTSQPIKADVLFIHGLMGAAFKTWRQQDSEQAVIEKPM EDEDRYTTCWPKTWLAKDCPALRIISVEYDTSLSDWRARCPMERKS IAFRSNELLRKLRAAGVGDRPVVWISHSMGGLLVKKMLLEASTKPE MSTVINNTRGIIFYSVPHHGSRLAEYSVNIRYLLFPSLEVKELSKDSP ALKTLQDDFLEFAKDKNFQVLNFVETLPTYIGSMIKLHVVPVESADL GIGDLIPVDVNHLNICKPKKKDAFLYQRTLQFIREALAKDLEN 170 MPAPRAPRALAAAAPASGKAKLTHPGKAILAGGLAGGIEICITFPTE SLC25A1 YVKTQLQLDERSHPPRYRGIGDCVRQTVRSHGVLGLYRGLSSLLYG SIPKAAVRFGMFEFLSNHMRDAQGRLDSTRGLLCGLGAGVAEAVV VVCPMETIKVKFIHDQTSPNPKYRGFFHGVREIVREQGLKGTYQGLT ATVLKQGSNQAIRFFVMTSLRNWYRGDNPNKPMNPLITGVFGAIAG AASVFGNTPLDVIKTRMQGLEAHKYRNTWDCGLQILKKEGLKAFY KGTVPRLGRVCLDVAIVFVIYDEV VKLLNKVWKTD 171 MAASMFYGRLVAVATLRNHRPRTAQRAAAQVLGSSGLFNNHGLQ SUCLA2 VQQQQQRNLSLHEYMSMELLQEAGVSVPKGYVAKSPDEAYAIAKK LGSKDVVIKAQVLAGGRGKGTFESGLKGGVKIVFSPEEAKAVSSQM IGKKLFTKQTGEKGRICNQVLVCERKYPRREYYFAITMERSFQGPVL IGSSHGGVNIEDVAAESPEAIIKEPIDIEEGIKKEQALQLAQKMGFPPN IVESAAENMVKLYSLFLKYDATMIEINPMVEDSDGAVLCMDAKINF DSNSAYRQKKIFDLQDWTQEDERDKDAAKANLNYIGLDGNIGCLV NGAGLAMATMDIIKLHGGTPANFLDVGGGATVHQVTEAFKLITSDK KVLAILVNIFGGIMRCDVIAQGIVMAVKDLEIKIPVVVRLQGTRVDD AKALIADSGLKILACDDLDEAARMVVKLSEIVTLAKQAHVDVKFQL PI 172 MTATLAAAADIATMVSGSSGLAAARLLSRSFLLPQNGIRHCSYTAS SUCLG1 RQHLYVDKNTKIICQGFTGKQGTFHSQQALEYGTKLVGGTTPGKGG QTHLGLPVFNTVKEAKEQTGATASVIYVPPPFAAAAINEAIEAEIPLV VCITEGIPQQDMVRVKHKLLRQEKTRLIGPNCPGVINPGECKIGIMP GHIHKKGRIGIVSRSGTLTYEAVHQTTQVGLGQSLCVGIGGDPFNGT DFIDCLEIFLNDSATEGIILIGEIGGNAEENAAEFLKQHNSGPNSKPVV SFIAGLTAPPGRRMGHAGAIIAGGKGGAKEKISALQSAGVVVSMSP AQLGTTIYKEFEKRKML 173 MPLHVKWPFPAVPPLTWTLASSVVMGLVGTYSCFWTKYMNHLTV TAZ HNREVLYELIEKRGPATPLITVSNHQSCMDDPHLWGILKLRHIWNLK LMRWTPAAADICFTKELHSHFFSLGKCVPVCRGAEFFQAENEGKGV LDTGRHMPGAGKRREKGDGVYQKGMDFILEKLNHGDWVHIFPEG KVNMSSEFLRFKWGIGRLIAECHLNPIILPLWHVGMNDVLPNSPPYF PRFGQKITVLIGKPFSALPVLERLRAENKSAVEMRKALTDFIQEEFQ HLKTQAEQLHNHLQPGR 174 MTVFFKTLRNHWKKTTAGLCLLTWGGHWLYGKHCDNLLRRAACQ AGK EAQVFGNQLIPPNAQVKKATVFLNPAACKGKARTLFEKNAAPILHL SGMDVTIVKTDYEGQAKKLLELMENTDVIIVAGGDGTLQEVVTGV LRRTDEATFSKIPIGFIPLGETSSLSHTLFAESGNKVQHITDATLAIVK GETVPLDVLQIKGEKEQPVFAMTGLRWGSFRDAGVKVSKYWYLGP LKIKAAHFFSTLKEWPQTHQASISYTGPTERPPNEPEETPVQRPSLYR RILRRLASYWAQPQDALSQEVSPEVWKDVQLSTIELSITTRNNQLDP TSKEDFLNICIEPDTISKGDFITIGSRKVRNPKLHVEGTECLQASQCTL LIPEGAGGSFSIDSEEYEAMPVEVKLLPRKLQFFCDPRKREQMLTSPT Q 175 MLGSLVLRRKALAPRLLLRLLRSPTLRGHGGASGRNVTTGSLGEPQ CLPB WLRVATGGRPGTSPALFSGRGAATGGRQGGRFDTKCLAAATWGRL PGPEETLPGQDSWNGVPSRAGLGMCALAAALVVHCYSKSPSNKDA ALLEAARANNMQEVSRLLSEGADVNAKHRLGWTALMVAAINRNN SVVQVLLAAGADPNLGDDFSSVYKTAKEQGIHSLEDGGQDGASRHI TNQWTSALEFRRWLGLPAGVLITREDDFNNRLNNRASFKGCTALH YAVLADDYRTVKELLDGGANPLQRNEMGHTPLDYAREGEVMKLL RTSEAKYQEKQRKREAEERRRFPLEQRLKEHIIGQESAIATVGAA IRRKENGWYDEEHPLVFLFLGSSGIGKTELAKQTAKYMHKDAKKG FIRLDMSEFQERHEVAKFIGSPPGYVGHEEGGQLTKKLKQCPNAVV LFDEVDKAHPDVLTIMLQLFDEGRLTDGKGKTIDCKDAIFIMTSNVA SDEIAQHALQLRQEALEMSRNRIAENLGDVQISDKITISKNFKENVIR PILKAHFRRDEFLGRINEIVYFLPFCHSELIQLVNKELNFWAKRAKQR HNITLLWDREVADVLVDGYNVHYGARSIKHEVERRVVNQLAAAYE QDLLPGGCTLRITVEDSDKQLLKSPELPSPQAEKRLPKLRLEIIDKDS KTRRLDIRAPLHPEKVCNTI 176 MLFLALGSPWAVELPLCGRRTALCAAAALRGPRASVSRASSSSGPS TMEM70 GPVAGWSTGPSGAARLLRRPGRAQIPVYWEGYVRFLNTPSDKSEDG RLIYTGNMARAVFGVKCFSYSTSLIGLTFLPYIFTQNNAISESVPLPIQ IIFYGIMGSFTVITPVLLHFITKGYVIRLYHEATTDTYKAITYNAMLA ETSTVFHQNDVKIPDAKHVFTTFYAKTKSLLVNPVLFPNREDYIHLM GYDKEEFILYMEETSEEKRHKDDK 177 MLSQVYRCGFQPFNQHLLPWVKCTTVFRSHCIQPSVIRHVRSWSNIP ALDH18A1 FITVPLSRTHGKSFAHRSELKHAKRIVVKLGSAVVTRGDECGLALGR LASIVEQVSVLQNQGREMMLVTSGAVAFGKQRLRHEILLSQSVRQA LHSGQNQLKEMAIPVLEARACAAAGQSGLMALYEAMFTQYSICAA QILVTNLDFHDEQKRRNLNGTLHELLRMNIVPIVNTNDAVVPPAEP NSDLQGVNVISVKDNDSLAARLAVEMKTDLLIVLSDVEGLFDSPPG SDDAKLIDIFYPGDQQSVTFGTKSRVGMGGMEAKVKAALWALQGG TSVVIANGTHPKVSGHVITDIVEGKKVGTFFSEVKPAGPTVEQQGE MARSGGRMLATLEPEQRAEIIHHLADLLTDQRDEILLANKKDLEEA EGRLAAPLLKRLSLSTSKLNSLAIGLRQIAASSQDSVGRVLRRTRIAK NLELEQVTVPIGVLLVIFESRPDCLPQVAALAIASGNGLLLKGGKEA AHSNRILHLLTQEALSIHGVKEAVQLVNTREEVEDLCRLDKMIDLIIP RGSSQLVRDIQKAAKGIPVMGHSEGICHMYVDSEASVDKVTRLVRD SKCEYPAACNALETLLIHRDLLRTPLFDQIIDMLRVEQVKIHAGPKF ASYLTFSPSEVKSLRTEYGDLELCIEVVDNVQDAIDHIHKYGSSHTD VIVTEDENTAEFFLQHVDSACVFWNASTRFSDGYRFGLGAEVGISTS RIHARGPVGLEGLLTTKWLLRGKDHVVSDFSEHGSLKYLHENLPIP QRNTN 178 MFSKLAHLQRFAVLSRGVHSSVASATSVATKKTVQGPPTSDDIFERE OAT YKYGAHNYHPLPVALERGKGIYLWDVEGRKYFDFLSSYSAVNQGH CHPKIVNALKSQVDKLTLTSRAFYNNVLGEYEEYITKLFNYHKVLP MNTGVEAGETACKLARKWGYTVKGIQKYKAKIVFAAGNFWGRTL SAISSSTDPTSYDGFGPFMPGFDIIPYNDLPALERALQDPNVAAFMVE PIQGEAGVVVPDPGYLMGVRELCTRHQVLFIADEIQTGLARTGRWL AVDYENVRPDIVLLGKALSGGLYPVSAVLCDDDIMLTIKPGEHGST YGGNPLGCRVAIAALEVLEEENLAENADKLGIILRNELMKLPSDVVT AVRGKGLLNAIVIKETKDWDAWKVCLRLRDNGLLAKPTHGDIIRFA PPLVIKEDELRESIEIINKTILSF 179 MLGRNTWKTSAFSFLVEQMWAPLWSRSMRPGRWCSQRSCAWQTS CA5A NNTLHPLWTVPVSVPGGTRQSPINIQWRDSVYDPQLKPLRVSYEAA SCLYIWNTGYLFQVEFDDATEASGISGGPLENHYRLKQFHFHWGAV NEGGSEHTVDGHAYPAELHLVHWNSVKYQNYKEAVVGENGLAVI GVFLKLGAHHQTLQRLVDILPEIKHKDARAAMRPFDPSTLLPTCWD YWTYAGSLTTPPLTESVTWIIQKEPVEVAPSQLSAFRTLLFSALGEEE KMMVNNYRPLQPLMNRKVWASFQATNEGTRS 180 MYRYLGEALLLSRAGPAALGSASADSAALLGWARGQPAAAPQPGL GLUD1 ALAARRHYSEAVADREDDPNFFKMVEGFFDRGASIVEDKLVEDLRT RESEEQKRNRVRGILRIIKPCNHVLSLSFPIRRDDGSWEVIEGYRAQH SQHRTPCKGGIRYSTDVSVDEVKALASLMTYKCAVVDVPFGGAKA GVKINPKNYTDNELEKITRRFTMELAKKGFIGPGIDVPAPDMSTGER EMSWIADTYASTIGHYDINAHACVTGKPISQGGIHGRISATGRGVFH GIENFINEASYMSILGMTPGFG DKTFVVQGFGNVGLHSMRYLHRFGAKCIAVGESDGSIWNPDGIDPK ELEDFKLQHGSILGFPKAKPYEGSILEADCDILIPAASEKQLTKSNAP RVKAKIIAEGANGPTTPEADKIFLERNIMVIPDLYLNAGGVTVSYFE WLKNLNHVSYGRLTFKYERDSNYHLLMSVQESLERKFGKHGGTIPI VPTAEFQDRISGASEKDIVHSGLAYTMERSARQIMRTAMKYNLGLD LRTAAYVNAIEKVFKVYNEAGVTFT 181 MTTSASSHLNKGIKQVYMSLPQGEKVQAMYIWIDGTGEGLRCKTR GLUL TLDSEPKCVEELPEWNFDGSSTLQSEGSNSDMYLVPAAMFRDPFRK DPNKLVLCEVFKYNRRPAETNLRHTCKRIMDMVSNQHPWFGMEQE YTLMGTDGHPFGWPSNGFPGPQGPYYCGVGADRAYGRDIVEAHYR ACLYAGVKIAGTNAEVMPAQWEFQIGPCEGISMGDHLWVARFILH RVCEDFGVIATFDPKPIPGNWNGAGCHTNFSTKAMREENGLKYIEE AIEKLSKRHQYHIRAYDPKGGLDNARRLTGFHETSNINDFSAGVAN RSASIRIPRTVGQEKKGYFEDRRPSANCDPFSVTEALIRTCLLNETGD EPFQYKN 182 MAVARAALGPLVTGLYDVQAFKFGDFVLKSGLSSPIYIDLRGIVSRP UMPS RLLSQVADILFQTAQNAGISFDTVCGVPYTALPLATVICSTNQIPMLI RRKETKDYGTKRLVEGTINPGETCLIIEDVVTSGSSVLETVEVLQKE GLKVTDAIVLLDREQGGKDKLQAHGIRLHSVCTLSKMLEILEQQKK VDAETVGRVKRFIQENVFVAANHNGSPLSIKEAPKELSFGARAELPR IHPVA SKLLRLMQKKETNLCLSADVSLARELLQLADALGPSICMLKTHVDI LNDFTLDVMKELITLAKCHEFLIFEDRKFADIGNTVKKQYEGGIFKIA SWADLVNAHVVPGSGVVKGLQEVGLPLHRGCLLIAEMSSTGSLAT GDYTRAAVRMAEEHSEFVVGFISGSRVSMKPEFLHLTPGVQLEAGG DNLGQQYNSPQEVIGKRGSDIIIVGRGIISAADRLEAAEMYRKAAWE AYLSRLGV 183 MRDYDEVTAFLGEWGPFQRLIFFLLSASIIPNGFTGLSSVFLIATPEHR SLC22A5 CRVPDAANLSSAWRNHTVPLRLRDGREVPHSCRRYRLATIANFSAL GLEPGRDVDLGQLEQESCLDGWEFSQDVYLSTIVTEWNLVCEDDW KAPLTISLFFVGVLLGSFISGQLSDRFGRKNVLFVTMGMQTGFSFLQI FSKNFEMFVVLFVLVGMGQISNYVAAFVLGTEILGKSVRIIFSTLGV CIFYAFGYMVLPLFAYFIRDWRMLLVALTMPGVLCVALWWFIPESP RWLISQGRFEEAEVIIRKAAKANGIVVPSTIFDPSELQDLSSKKQQSH NILDLLRTWNIRMVTIMSIMLWMTISVGYFGLSLDTPNLHGDIFVNC FLSAMVEVPAYVLAWLLLQYLPRRYSMATALFLGGSVLLFMQLVP PDLYYLATVLVMVGKFGVTAAFSMVYVYTAELYPTVVRNMGVGV SSTASRLGSILSPYFVYLGAYDRFLPYILMGSLTILTAILTLFLPESFGT PLPDTIDQMLRVKGMKHRKTPSHTR MLKDGQERPTILKSTAF 184 MAEAHQAVAFQFTVTPDGIDLRLSHEALRQIYLSGLHSWKKKFIRF CPT1A KNGIITGVYPASPSSWLIVVVGVMTTMYAKIDPSLGIIAKINRTLETA NCMSSQTKNVVSGVLFGTGLWVALIVTMRYSLKVLLSYHGWMFTE HGKMSRATKIWMGMVKIFSGRKPMLYSFQTSLPRLPVPAVKDTVN RYLQSVRPLMKEEDFKRMTALAQDFAVGLGPRLQWYLKLKSWWA TNYVSDWWEEYIYLRGRGPLMVNSNYYAMDLLYILPTHIQAARAG NAIHAILLYRRKLDREEIKPIRLLGSTIPLCSAQWERMFNTSRIPGEET DTIQHMRDSKHIVVYHRGRYFKVWLYHDGRLLKPREMEQQMQRIL DNTSEPQPGEARLAALTAGDRVPWARCRQAYFGRGKNKQSLDAVE KAAFFVTLDETEEGYRSEDPDTSMDSYAKSLLHGRCYDRWFDKSFT FVVFKNGKMGLNAEHSWADAPIVAHLWEYVMSIDSLQLGYAEDG HCKGDINPNIPYPTRLQWDIPGECQEVIETSLNTANLLANDVDFHSFP FVAFGKGIIKKCRTSPDAFVQLALQLAHYKDMGKFCLTYEASMTRL FREGRTETVRSCTTESCDFVRAMVDPAQTVEQRLKLFKLASEKHQH MYRLAMTGSGIDRHLFCLYVVSKYLAVESPFLKEVLSEPWRLSTSQ TPQQQVELFDLENNPEYVSSGGGFGPVADDGYGVSYILVGENLINF HISSKFSCPETDSHRFGRHLKEAMTDIITLFGLSSNSKK 185 MVACRAIGILSRFSAFRILRSRGYICRNFTGSSALLTRTHINYGVKGD HADHA VAVVRINSPNSKVNTLSKELHSEFSEVMNEIWASDQIRSAVLISSKPG CFIAGADINMLAACKTLQEVTQLSQEAQRIVEKLEKSTKPIVAAING SCLGGGLEVAISCQYRIATKDRKTVLGTPEVLLGALPGAGGTQRLP KMVGVPAALDMMLTGRSIRADRAKKMGLVDQLVEPLGPGLKPPEE RTIEYLEEVAITFAKGLADKKISPKRDKGLVEKLTAYAMTIPFVRQQ VYKKVEEKVRKQTKGLYPAPLKIIDVVKTGIEQGSDAGYLCESQKF GELVMTKESKALMGLYHGQVLCKKNKFGAPQKDVKHLAILGAGL MGAGIAQVSVDKGLKTILKDATLTALDRGQQQVFKGLNDKVKKKA LTSFERDSIFSNLTGQLDYQGFEKADMVIEAVFEDLSLKHRVLKEVE AVIPDHCIFASNTSALPISEIAAVSKRPEKVIGMHYFSPVDKMQLLEII TTEKTSKDTSASAVAVGLKQGKVIIVVK DGPGFYTTRCLAPMMSEVIRILQEGVDPKKLDSLTTSFGFPVGAATL VDEVGVDVAKHVAEDLGKVFGERFGGGNPELLTQMVSKGFLGRKS GKGFYIYQEGVKRKDLNSDMDSILASLKLPPKSEVSSDEDIQFRLVT RFVNEAVMCLQEGILATPAEGDIGAVFGLGFPPCLGGPFRFVDLYG AQKIVDRLKKYEAAYGKQFTPCQLLADHANSPNKKFYQ 186 MAFVTRQFMRSVSSSSTASASAKKIIVKHVTVIGGGLMGAGIAQVA HADH AATGHTVVLVDQTEDILAKSKKGIEESLRKVAKKKFAENLKAGDEF VEKTLSTIATSTDAASVVHSTDLVVEAIVENLKVKNELFKRLDKFAA EHTIFASNTSSLQITSIANATTRQDRFAGLHFFNPVPVMKLVEVIKTP MTSQKTFESLVDFSKALGKHPVSCKDTPGFIVNRLLVPYLMEAIRLY ERGDASKEDIDTAMKLGAGYPMGPFELLDYVGLDTTKFIVDGWHE MDAENPLHQPSPSLNKLVAENKFGKKTGEGFYKYK 187 MAAPTLGRLVLTHLLVALFGMGSWAAVNGIWVELPVVVKDLPEG SLC52A1 WSLPSYLSVVVALGNLGLLVVTLWRQLAPGKGEQVPIQVVQVLSV VGTALLAPLWHHVAPVAGQLHSVAFLTLALVLAMACCTSNVTFLP FLSHLPPPFLRSFFLGQGLSALLPCVLALVQGVGRLECPPAPTNGTSG PPLDFPERFPASTFFWALTALLVTSAAAFRGLLLLLPSLPSVTTGGSG PELQLGSPGAEEEEKEEEEALPLQEPPSQAAGTIPGPDPEAHQLFSAH GAFLLGLMAFTSAVTNGVLPSVQSFSCLPYGRLAYHLAVVLGSAAN PLACFLAMGVLCRSLAGLVGLSLLGMLFGAYLMALAILSPCPPLVG TTAGVVLVVLSWVLCLCVFSYVKVAASSLLHGGGRPALLAAGVAI QVGSLLGAGAMFPPTSIYHVFQSRKDCVDPCGP 188 MAAPTPARPVLTHLLVALFGMGSWAAVNGIWVELPVVVKELPEG SLC52A2 WSLPSYVSVLVALGNLGLLVVTLWRRLAPGKDEQVPIRVVQVLGM VGTALLASLWHHVAPVAGQLHSVAFLALAFVLALACCASNVTFLP FLSHLPPRFLRSFFLGQGLSALLPCVLALVQGVGRLECPPAPINGTPG PPLDFLERFPASTFFWALTALLVASAAAFQGLLLLLPPPPSVPTGELG SGLQVGAPGAEEEVEESSPLQEPPSQAAGTTPGPDPKAYQLLSARSA CLLGLLAATNALTNGVLPAVQSFSCLPYGRLAYHLAVVLGSAANPL ACFLAMGVLCRSLAGLGGLSLLGVFCGGYLMALAVLSPCPPLVGTS AGVVLVVLSWVLCLGVFSYVKVAASSLLHGGGRPALLAAGVAIQV GSLLGAVAMFPPTSIYHVFHSRKDCADPCDS 189 MAFLMHLLVCVFGMGSWVTINGLWVELPLLVMELPEGWYLPSYLT SLC52A3 VVIQLANIGPLLVTLLHHFRPSCLSEVPIIFTLLGVGTVTCIIFAFLWN MTSWVLDGHHSIAFLVLTFFLALVDCTSSVTFLPFMSRLPTYYLTTF FVGEGLSGLLPALVALAQGSGLTTCVNVTEISDSVPSPVPTRETDIAQ GVPRALVSALPGMEAPLSHLESRYLPAHFSPLVFFLLLSIMMACCLV AFFV LQRQPRCWEASVEDLLNDQVTLHSIRPREENDLGPAGTVDSSQGQG YLEEKAAPCCPAHLAFIYTLVAFVNALTNGMLPSVQTYSCLSYGPV AYHLAATLSIVANPLASLVSMFLPNRSLLFLGVLSVLGTCFGGYNM AMAVMSPCPLLQGHWGGEVLIVASWVLFSGCLSYVKVMLGVVLR DLSRSALLWCGAAVQLGSLLGALLMFPLVNVLRLFSSADFCNLHCP A 190 MTILTYPFKNLPTASKWALRFSIRPLSCSSQLRAAPAVQTKTKKTLA HADHB KPNIRNVVVVDGVRTPFLLSGTSYKDLMPHDLARAALTGLLHRTSV PKEVVDYIIFGTVIQEVKTSNVAREAALGAGFSDKTPAHTVTMACIS ANQAMTTGVGLIASGQCDVIVAGGVELMSDVPIRHSRKMRKLMLD LNKAKSMGQRLSLISKFRFNFLAPELPAVSEFSTSETMGHSADRLAA AFAVSRLEQDEYALRSHSLAKKAQDEGLLSDVVPFKVPGKDTVTK DNGIRPSSLEQMAKLKPAFIKPY GTVTAANSSFLTDGASAMLIMAEEKALAMGYKPKAYLRDFMYVSQ DPKDQLLLGPTYATPKVLEKAGLTMNDIDAFEFHEAFSGQILANFK AMDSDWFAENYMGRKTKVGLPPLEKFNNWGGSLSLGHPFGATGC RLVMAAANRLRKEGGQYGLVAACAAGGQGHAMIVEAYPK 191 MLRGRSLSVTSLGGLPQWEVEELPVEELLLFEVAWEVTNKVGGIYT GYS2 VIQTKAKTTADEWGENYFLIGPYFEHNMKTQVEQCEPVNDAVRRA VDAMNKHGCQVHFGRWLIEGSPYVVLFDIGYSAWNLDRWKGDLW EACSVGIPYHDREANDMLIFGSLTAWFLKEVTDHADGKYVVAQFH EWQAGIGLILSRARKLPIATIFTTHATLLGRYLCAANIDFYNHLDKFN IDKEAGERQIYHRYCMERASVHCAHVFTTVSEITAIEAEHMLKRKP DVVTPNGLNVKKFSAVHEFQNLHAMYKARIQDFVRGHFYGHLDFD LEKTLFLFIAGRYEFSNKGADIFLESLSRLNFLLRMHKSDITVMVFFI MPAKTNNFNVETLKGQAVRKQLWDVAHSVKEKFGKKLYDALLRG EIPDLNDILDRDDLTIMKRAIFSTQRQSLPPVTTHNMIDDSTDPILSTI RRIGLFNNRTDRVKVILHPEFLSSTSPLLPMDYEEFVRGCHLGVFPSY YEPWGYTPAECTVMGIPSVTTNLSGFGCFMQEHVADPTAYGIYIVD RRFRSPDDSCNQLTKFLYGFCKQSRRQRIIQRNRTERLSDLLDWRYL GRYYQHARHLTLSRAFPDKFHVELTSPPTTEGFKYPRPSSVPPSPSGS QASSPQSSDVEDEVEDERYDEEEEAERDRLNIKSPFSLSHVPHGKKK LHGEYKN 192 MAKPLTDQEKRRQISIRGIVGVENVAELKKSFNRHLHFTLVKDRNV PYGL ATTRDYYFALAHTVRDHLVGRWIRTQQHYYDKCPKRVYYLSLEFY MGRTLQNTMINLGLQNACDEAIYQLGLDIEELEEIEEDAGLGNGGL GRLAACFLDSMATLGLAAYGYGIRYEYGIFNQKIRDGWQVEEADD WLRYGNPWEKSRPEFMLPVHFYGKVEHTNTGTKWIDTQVVLALPY DTPVPGYMNNTVNTMRLWSARAPNDFNLRDFNVGDYIQAVLDRN LAENISRVLYPNDNFFEGKELRLKQEYFVVAATLQDIIRRFKASKFG STRGAGTVFDAFPDQVAIQLNDTHPALAIPELMRIFVDIEKL PWSKAWELTQKTFAYTNHTVLPEALERWPVDLVEKLLPRHLEIIYEI NQKHLDRIVALFPKDVDRLRRMSLIEEEGSKRINMAHLCIVGSHAV NGVAKIHSDIVKTKVFKDFSELEPDKFQNKTNGITPRRWLLLCNPGL AELIAEKIGEDYVKDLSQLTKLHSFLGDDVFLRELAKVKQENKLKFS QFLETEYKVKINPSSMFDVQVKRIHEYKRQLLNCLHVITMYNRIKK DPKKLFVPRTVIIGGKAAPGYHMAKMIIKLITSVADVVNNDPMVGS KLKVIFLENYRVSLAEKVIPATDLSEQISTAGTEASGTGNMKFMLNG ALTIGTMDGANVEMAEEAGEENLFIFGMRIDDVAALDKKGYEAKE YYEALPELKLVIDQIDNGFFSPKQPDLFKDIINMLFYHDRFKVFADY EAYVKCQDKVSQLYMNPKAWNTMVLKNIAASGKFSSDRTIKEYAQ NIWNVEPSDLKISLSNESNKVNGN 193 MTEDKVTGTLVFTVITAVLGSFQFGYDIGVINAPQQVIISHYRHVLG SLC2A2 VPLDDRKAINNYVINSTDELPTISYSMNPKPTPWAEEETVAAAQLIT MLWSLSVSSFAVGGMTASFFGGWLGDTLGRIKAMLVANILSLVGA LLMGFSKLGPSHILIIAGRSISGLYCGLISGLVPMYIGEIAPTALRGAL GTFHQLAIVTGILISQIIGLEFILGNYDLWHILLGLSGVRAILQSLLLFF CPESPRYLYIKLDEEVKAKQSLKRLRGYDDVTKDINEMRKEREEAS SEQKVSIIQLFTNSSYRQPILVALMLHVAQQFSGINGIFYYSTSIFQTA GISKPVYATIGVGAVNMVFTAVSVFLVEKAGRRSLFLIGMSGMFVC AIFMSVGLVLLNKFSWMSYVSMIAIFLFVSFFEIGPGPIPWFMVAEFF SQGPRPAALAIAAFSNWTCNFIVALCFQYIADFCGPYVFFLFAGVLL AFTLFTFFKVPETKGKSFEEIAAEFQKKSGSAHRPKAAVEMKFLGAT ETV 194 MAASCLVLLALCLLLPLLLLGGWKRWRRGRAARHVVAVVLGDVG ALG1 RSPRMQYHALSLAMHGFSVTLLGFCNSKPHDELLQNNRIQIVGLTE LQSLAVGPRVFQYGVKVVLQAMYLLWKLMWREPGAYIFLQNPPG LPSIAVCWFVGCLCGSKLVIDWHNYGYSIMGLVHGPNHPLVLLAK WYEKFFGRLSHLNLCVTNAMREDLADNWHIRAVTVYDKPASFFKE TPLDLQHRLFMKLGSMHSPFRARSEPEDPVTERSAFTERDAGSGLVT RLRERPALLVSSTSWTEDEDFSILLAALEKFEQLTLDGHNLPSLVCVI TGKGPLREYYSRLIHQKHFQHIQVCTPWLEAEDYPLLLGSADLGVC LHTSSSGLDLPMKVVDMFGCCLPVCAVNFKCLHELVKHEENGLVF EDSEELAAQLQMLFSNFPDPAGKLNQFRKNLRESQQLRWDESWVQ TVLPLVMDT 195 MAEEQGRERDSVPKPSVLFLHPDLGVGGAERLVLDAALALQARGC ALG2 SVKIWTAHYDPGHCFAESRELPVRCAGDWLPRGLGWGGRGAAVC AYVRMVFLALYVLFLADEEFDVVVCDQVSACIPVFRLARRRKKILF YCHFPDLLLTKRDSFLKRLYRAPIDWIEEYTTGMADCILVNSQFTAA VFKETFKSLSHIDPDVLYPSLNVTSFDSVVPEKLDDLVPKGKKFLLL SINRYERKKNLTLALEALVQLRGRLTSQDWERVHLIVAGGYDERVL ENVEHYQELKKMVQQSDLGQYVTFLRSFSDKQKISLLHSCTCVLYT PSNEHFGIVPLEAMYMQCPVIAVNSGGPLESIDHSVTGFLCEPDPVH FSEAIEKFIREPSLKATMGLAGRARVKEKFSPEAFTEQLYRYVTKLL V 196 MAAGLRKRGRSGSAAQAEGLCKQWLQRAWQERRLLLREPRYTLL ALG3 VAACLCLAEVGITFWVIHRVAYTEIDWKAYMAEVEGVINGTYDYT QLQGDTGPLVYPAGFVYIFMGLYYATSRGTDIRMAQNIFAVLYLAT LLLVFLIYHQTCKVPPFVFFFMCCASYRVHSIFVLRLFNDPVAMVLL FLSINLLLAQRWGWGCCFFSLAVSVKMNVLLFAPGLLFLLLTQFGF RGALPKLGICAGLQVVLGLPFLLENPSGYLSRSFDLGRQFLFHWTVN WRFLPEALFLHRAFHLALLTAHLTL LLLFALCRWHRTGESILSLLRDPSKRKVPPQPLTPNQIVSTLFTSNFIG ICFSRSLHYQFYVWYFHTLPYLLWAMPARWLTHLLRLLVLGLIELS WNTYPSTSCSSAALHICHAVILLQLWLGPQPFPKSTQHSKKAH 197 MEKWYLMTVVVLIGLTVRWTVSLNSYSGAGKPPMFGDYEAQRHW ALG6 QEITFNLPVKQWYFNSSDNNLQYWGLDYPPLTAYHSLLCAYVAKFI NPDWIALHTSRGYESQAHKLFMRTTVLIADLLIYIPAVVLYCCCLKE ISTKKKIANALCILLYPGLILIDYGHFQYNSVSLGFALWGVLGISCDC DLLGSLAFCLAINYKQMELYHALPFFCFLLGKCFKKGLKGKGFVLL VKLACIVVASFVLCWLPFFTEREQTLQVLRRLFPVDRGLFEDKVANI WCSFNVFLKIKDILPRHIQLIMSFCSTFLSLLPACIKLILQPSSKGFKFT LVSCALSFFLFSFQVHEKSILLVSLPVCLVLSEIPFMSTWFLLVSTFSM LPLLLKDELLMPSVVTTMAFFIACVTSFSIFEKTSEEELQLKSFSISVR KYLPCFTFLSRIIQYLFLISVITMVLLTLMTVTLDPPQKLPDLFSVLVC FVSCLNFLFFLVYFNIIIMWDSKSGRNQKKIS 198 MAALTIATGTGNWFSALALGVTLLKCLLIPTYHSTDFEVHRNWLAI ALG8 THSLPISQWYYEATSEWTLDYPPFFAWFEYILSHVAKYFDQEMLNV HNLNYSSSRTLLFQRFSVIFMDVLFVYAVRECCKCIDGKKVGKELTE KPKFILSVLLLWNFGLLIVDHIHFQYNGFLFGLMLLSIARLFQKRHM EGAFLFAVLLHFKHIYLYVAPAYGVYLLRSYCFTANKPDGSIRWKS FSFVRVISLGLVVFLVSALSLGPFLALNQLPQVFSRLFPFKRGLCHAY WAPNFWALYNALDKVLSVIGLKLKFLDPNNIPKASMTSGLVQQFQ HTVLPSVTPLATLICTLIAILPSIFCLWFKPQGPRGFLRCLTLCALSSF MFGWHVHEKAILLAILPMSLLSVGKAGDASIFLILTTTGHYSLFPLLF TAPELPIKILLMLLFTIYSISSLKTLFRKEKPLFNWMETFYLLGLGPLE VCCEFVFPFTSWKVKYPFIPLLLTSVYCAVGITYAWFKLYVSVLIDS AIGKTKKQ 199 MASRGARQRLKGSGASSGDTAPAADKLRELLGSREAGGAEHRTEL ALG9 SGNKAGQVWAPEGSTAFKCLLSARLCAALLSNISDCDETFNYWEPT HYLIYGEGFQTWEYSPAYAIRSYAYLLLHAWPAAFHARILQTNKILV FYFLRCLLAFVSCICELYFYKAVCKKFGLHVSRMMLAFLVLSTGMF CSSSAFLPSSFCMYTTLIAMTGWYMDKTSIAVLGVAAGAILGWPFS AALGLPIAFDLLVMKHRWKSFFHWSLMALILFLVPVVVIDSYYYGK LVIAPLNIVLYNVFTPHGPDLYGT EPWYFYLINGFLNFNVAFALALLVLPLTSLMEYLLQRFHVQNLGHP YWLTLAPMYIWFIIFFIQPHKEERFLFPVYPLICLCGAVALSALQKCY HFVFQRYRLEHYTVTSNWLALGTVFLFGLLSFSRSVALFRGYHGPL DLYPEFYRIATDPTIHTVPEGRPVNVCVGKEWYRFPSSFLLPDNWQL QFIPSEFRGQLPKPFAEGPLATRIVPTDMNDQNLEEPSRYIDISKCHY LVDLDTMRETPREPKYSSNKEEWISLAYRPFLDASRSSKLLRAFYVP FLSDQYTVYVNYTILKPRKAKQIRKKSGG 200 MAAGERSWCLCKLLRFFYSLFFPGLIVCGTLCVCLVIVLWGIRLLLQ ALG11 RKKKLVSTSKNGKNQMVIAFFHPYCNAGGGGERVLWCALRALQK KYPEAVYVVYTGDVNVNGQQILEGAFRRFNIRLIHPVQFVFLRKRY LVEDSLYPHFTLLGQSLGSIFLGWEALMQCVPDVYIDSMGYAFTLPL FKYIGGCQVGSYVHYPTISTDMLSVVKNQNIGFNNAAFITRNPFLSK VKLIYYYLFAHYGLVGSCSDVVMVNSSWTLNHILSLWKVGNCTNI VYPPCDVQTFLDIPLHEKKMTPGHLLVSVGQFRPEKNHPLQIRAFAK LLNKKMVESPPSLKLVLIGGCRNKDDELRVNQLRRLSEDLGVQEYV EFKINIPFDELKNYLSEATIGLHTMWNEHFGIGVVECMAAGTIILAH NSGGPKLDIVVPHEGDITGFLAESEEDYAETIAHILSMSAEKRLQIRK SARASVSRFSDQEFEVTFLSSVEKLFK 201 MAGKGSSGRRPLLLGLLVAVATVHLVICPYTKVEESFNLQATHDLL ALG12 YHWQDLEQYDHLEFPGVVPRTFLGPVVIAVFSSPAVYVLSLLEMSK FYSQLIVRGVLGLGVIFGLWTLQKEVRRHFGAMVATMFCWVTAM QFHLMFYCTRTLPNVLALPVVLLALAAWLRHEWARFIWLSAFAIIV FRVELCLFLGLLLLLALGNRKVSVVRALRHAVPAGILCLGLTVAVD SYFWRQLTWPEGKVLWYNTVLNKSSNWGTSPLLWYFYSALPRGL GCSLLFIPLGLVDRRTHAPTVLALGFMALYSLLPHKELRFIIYAFPML NITAARGCSYLLNNYKKSWLYKAGSLLVIGHLVVNAAYSATALYV SHFNYPGGVAMQRLHQLVPPQTDVLLHIDVAAAQTGVSRFLQVNS AWRYDKREDVQPGTGMLAYTHILMEAAPGLLALYRDTHRVLASV VGTTGVSLNLTQLPPFNVHLQTKLVLLERLPRPS 202 MKCVFVTVGTTSFDDLIACVSAPDSLQKIESLGYNRLILQIGRGTVV ALG13 PEPFSTESFTLDVYRYKDSLKEDIQKADLVISHAGAGSCLETLEKGK PLVVVINEKLMNNHQLELAKQLHKEGHLFYCTCRVLTCPGQAKSIA SAPGKCQDSAALTSTAFSGLDFGLLSGYLHKQALVTATHPTCTLLFP SCHAFFPLPLTPTLYKMHKGWKNYCSQKSLNEASMDEYLGSLGLFR KLTAKDASCLFRAISEQLFCSQVHHLEIRKACVSYMRENQQTFESYV EGSFEKYLERLGDPKESAGQLEIRALSLIYNRDFILYRFPGKPPTYVT DNGYEDKILLCYSSSGHYDSVYSKQFQSSAAVCQAVLYEILYKDVF VVDEEELKTAIKLFRSGSKKNRNNAVTGSEDAHTDYKSSNQNRME EWGACYNAENIPEGYNKGTEETKSPENPSKMPFPYKVLKALDPEIY RNVEFDVWLDSRKELQKSDYMEYAGRQYYLGDKCQVCLESEGRY YNAHIQEVGNENNSVTVFIEELAEKHVVPLANLKPVTQVMSVPAW NAMPSRKGRGYQKMPGGYVPEIVISEMDIKQQKKMFKKIRGKEVY M TMAYGKGDPLLPPRLQHSMHYGHDPPMHYSQTAGNVMSNEHFHP QHPSPRQGRGYGMPRNSSRFINRHNMPGPKVDFYPGPGKRCCQSYD NFSYRSRSFRRSHRQMSCVNKESQYGFTPGNGQMPRGLEETITFYE VEEGDETAYPTLPNHGGPSTMVPATSGYCVGRRGHSSGKQTLNLEE GNGQSENGRYHEEYLYRAEPDYETSGVYSTTASTANLSLQDRKSCS MSPQDTVTSYNYPQKMMGNIAAVAASCANNVPAPVLSNGAAANQ AISTTSVSSQNAIQPLFVSPPTHGRPVIASPSYPCHSAIPHAGASLPPPP PPPPPPPPPPPPPPPPPPPPPPPALDVGETSNLQPPPPLPPPPYSCDPSGS DLPQDTKVLQYYFNLGLQCYYHSYWHSMVYVPQMQQQLHVENYP VYTEPPLVDQTVPQCYSEVRREDGIQAEASANDTFPNADSSSVPHG AVYYPVMSDPYGQPPLPGFDSCLPVVPDYSCVPPWHPVGTAYGGSS QIHGAINPGPIGCIAPSPPASHYVPQGM 203 MGSLFRSETMCLAQLFLQSGTAYECLSALGEKGLVQFRDLNQNVSS ATP6V0A2 FQRKFVGEVKRCEELERILVYLVQEINRADIPLPEGEASPPAPPLKQV LEMQEQLQKLEVELREVTKNKEKLRKNLLELIEYTHMLRVTKTFVK RNVEFEPTYEEFPSLESDSLLDYSCMQRLGAKLGFVSGLINQGKVEA FEKMLWRVCKGYTIVSYAELDESLEDPETGEVIKWYVFLISFWGEQI GHKVKKICDCYHCHVYPYPNTAEERREIQEGLNTRIQDLYTVLHKT EDYLRQVLCKAAESVYSRVIQVKKMKAIYHMLNMCSFDVTNKCLI AEVWCPEADLQDLRRALEEGSRESGATIPSFMNIIPTKETPPTRIRTN KFTEGFQNIVDAYGVGSYREVNPALFTIITFPFLFAVMFGDFGHGFV MFLFALLLVLNENHPRLNQSQEIMRMFFNGRYILLLMGLFSVYTGLI YNDCFSKSVNLFGSGWNVSAMYSSSHPPAEHKKMVLWNDSVVRH NSILQLDPSIPGVFRGPYPLGIDPIWNLATNRLTFLNSFKMKMSVILGI IHMTFGVILGIFNHLHFRKKFNIYLVSIPELLFMLCIFGYLIFMIFYKW LVFSAETSRVAPSILIEFINMFLFPASKTSGLYTGQEYVQRVLLVVTA LSVPVLFLGKPLFLLWLHNGRSCFGVNRSGYTLIRKDSEEEVSLLGS QDIEEGNHQVEDGCREMACEEFNFGEILMTQVIHSIEYCLGCISNTA SYLRLWALSLAHAQLSDVLWAMLMRVGLRVDTTYGVLLLLPVIAL FAVLTIFILLIMEGLSAFLHAIRLHWVEFQNKFYVGAGTKFVPF SFSLLSSKFNNDDSVA 204 MRPPACWWLLAPPALLALLTCSLAFGLASEDTKKEVKQSQDLEKS B3GLCT GISRKNDIDLKGIVFVIQSQSNSFHAKRAEQLKKSILKQAADLTQELP SVLLLHQLAKQEGAWTILPLLPHFSVTYSRNSSWIFFCEEETRIQIPK LLETLRRYDPSKEWFLGKALHDEEATIIHHYAFSENPTVFKYPDFAA GWALSIPLVNKLTKRLKSESLKSDFTIDLKHEIALYIWDKGGGPPLTP VPEF CTNDVDFYCATTFHSFLPLCRKPVKKKDIFVAVKTCKKFHGDRIPIV KQTWESQASLIEYYSDYTENSIPTVDLGIPNTDRGHCGKTFAILERFL NRSQDKTAWLVIVDDDTLISISRLQHLLSCYDSGEPVFLGERYGYGL GTGGYSYITGGGGMVFSREAVRRLLASKCRCYSNDAPDDMVLGMC FSGLGIPVTHSPLFHQARPVDYPKDYLSHQVPISFHKHWNIDPVKVY FTWLAPSDEDKARQETQKGFREEL 205 MFPRPLTPLAAPNGAEPLGRALRRAPLGRARAGLGGPPLLLPSMLM CHST14 FAVIVASSGLLLMIERGILAEMKPLPLHPPGREGTAWRGKAPKPGGL SLRAGDADLQVRQDVRNRTLRAVCGQPGMPRDPWDLPVGQRRTL LRHILVSDRYRFLYCYVPKVACSNWKRVMKVLAGVLDSVDVRLK MDHRSDLVFLADLRPEEIRYRLQHYFKFLFVREPLERLLSAYRNKFG EIREYQQRYGAEIVRRYRAGAGPSPAGDDVTFPEFLRYLVDEDPER MNEHWMPVYHLCQPCAVHYDFVGSYERLEADANQVLEWVRAPPH VRFPARQAWYRPASPESLHYHLCSAPRALLQDVLPKYILDFSLFAYP LPNVTKEACQQ 206 MATAATSPALKRLDLRDPAALFETHGAEEIRGLERQVRAEIEHKKE COG1 ELRQMVGERYRDLIEAADTIGQMRRCAVGLVDAVKATDQYCARLR QAGSAAPRPPRAQQPQQPSQEKFYSMAAQIKLLLEIPEKIWSSMEAS QCLHATQLYLLCCHLHSLLQLDSSSSRYSPVLSRFPILIRQVAAASHF RSTILHESKMLLKCQGVSDQAVAEALCSIMLLEESSPRQALTDFLLA RKATIQKLLNQPHHGAGIKAQICSLVELLATTLKQAHALFYTLPEGL LPDPALPCGLLFSTLETITGQHPAGKGTGVLQEEMKLCSWFKHLPAS IVEFQPTLRTLAHPISQEYLKDTLQKWIHMCNEDIKNGITNLLMYVK SMKGLAGIRDAMWELLTNESTNHSWDVLCRRLLEKPLLFWEDMM QQLFLDRLQTLTKEGFDSISSSSKELLVSALQELESSTSNSPSNKHIHF EYNMSLFLWSESPNDLPSDAAWVSVANRGQFASSGLSMKAQAISPC VQNFCSALDSKLKVKLDDLLAYLPSDD SSLPKDVSPTQAKSSAFDRYADAGTVQEMLRTQSVACIKHIVDCIRA ELQSIEEGVQGQQDALNSAKLHSVLFMARLCQSLGELCPHLKQCIL GKSESSEKPAREFRALRKQGKVKTQEIIPTQAKWQEVKEVLLQQSV MGYQVWSSAVVKVLIHGFTQSLLLDDAGSVLATATSWDELEIQEEA ESGSSVTSKIRLPAQPSWYVQSFLFSLCQEINRVGGHALPKVTLQEM LKSCMVQVVAAYEKLSEEKQIKKEGAFPVTQNRALQLLYDLRYLNI VLTAKGDEVKSGRSKPDSRIEK VTDHLEALIDPFDLDVFTPHLNSNLHRLVQRTSVLFGLVTGTENQLA PRSSTFNSQEPHNILPLASSQIRFGLLPLSMTSTRKAKSTRNIETKAQV VPPARSTAGDPTVPGSLFRQLVSEEDNTSAPSLFKLGWLSSMTK 207 MEKSRMNLPKGPDTLCFDKDEFMKEDFDVDHFVSDCRKRVQLEEL COG2 RDDLELYYKLLKTAMVELINKDYADFVNLSTNLVGMDKALNQLSV PLGQLREEVLSLRSSVSEGIRAVDERMSKQEDIRKKKMCVLRLIQVI RSVEKIEKILNSQSSKETSALEASSPLLTGQILERIATEFNQLQFHAVQ SKGMPLLDKVRPRIAGITAMLQQSLEGLLLEGLQTSDVDIIRHCLRT YATIDKTRDAEALVGQVLVKPYIDEVIIEQFVESHPNGLQVMYNKLL EFVPHHCRLLREVTGGAISSEKGNTVPGYDFLVNSVWPQIVQGLEE KLPSLFNPGNPDAFHEKYTISMDFVRRLERQCGSQASVKRLRAHPA YHSFNKKWNLPVYFQIRFREIAGSLEAALTDVLEDAPAESPYCLLAS HRTWSSLRRCWSDEMFLPLLVHRLWRLTLQILARYSVFVNELSLRPI SNESPKEIKKPLVTGSKEPSITQGNTEDQGSGPSETKPVVSISRTQLV YVVADLDKLQEQLPELLEIIKPKLEMIGFKNFSSISAALEDSQSSFSA CVPSLSSKIIQDLSDSCFGFLKSALEVPRLYRRTNKEVPTTASSYVDS ALKPLFQLQSGHKDKLKQAIIQQWLEGTLSESTHKYYETVSDVLNS VKKMEESLKRLKQARKTTPANPVGPSGGMSDDDKIRLQLALDVEY LGEQIQKLGLQASDIKSFSALAELVAAAKDQATAEQP 208 MADLDSPPKLSGVQQPSEGVGGGRCSEISAELIRSLTELQELEAVYE COG4 RLCGEEKVVERELDALLEQQNTIESKMVTLHRMGPNLQLIEGDAKQ LAGMITFTCNLAENVSSKVRQLDLAKNRLYQAIQRADDILDLKFCM DGVQTALRSEDYEQAAAHTHRYLCLDKSVIELSRQGKEGSMIDANL KLLQEAEQRLKAIVAEKFAIATKEGDLPQVERFFKIFPLLGLHEEGLR KFSEYLCKQVASKAEENLLMVLGTDMSDRRAAVIFADTLTLLFEGI ARIVETHQPIVETYYGPGRLYTLIKYLQVECDRQVEKVVDKFIKQRD YHQQFRHVQNNLMRNSTTEKIEPRELDPILTEVTLMNARSELYLRFL KKRISSDFEVGDSMASEEVKQEHQKCLDKLLNNCLLSCTMQELIGL YVTMEEYFMRETVNKAVALDTYEKGQLTSSMVDDVFYIVKKCIGR ALSSSSIDCLCAMINLATTELESDFRDVLCNKLRMGFPATTFQDIQR GVTSAVNIMHSSLQQGKFDTKGIESTDEAKMSFLVTLNNVEVCSENI STLKKTLESDCTKLFSQGIGGEQAQAKFDSCLSDLAAVSNKFRDLLQ EGLTELNSTAIKPQVQPWINSFFSVSHNIEEEEFNDYEANDPWVQQFI LNLEQQMAEFKASLSPVIYDSLTGLMTSLVAVELEKVVLKSTFNRL GGLQFDKELRSLIAYLTTVTTWTIRDKFARLSQMATILNLERVTEILD YWGPNSGPLTWRLTPAEVRQVLALRIDFRSEDIKRLRL 209 MGWVGGRRRDSASPPGRSRSAADDINPAPANMEGGGGSVAVAGL COG5 GARGSGAAAATVRELLQDGCYSDFLNEDFDVKTYTSQSIHQAVIAE QLAKLAQGISQLDRELHLQVVARHEDLLAQATGIESLEGVLQMMQ TRIGALQGAVDRIKAKIVEPYNKIVARTAQLARLQVACDLLRRIIRIL NLSKRLQGQLQGGSREITKAAQSLNELDYLSQGIDLSGIEVIENDLLF IARARLEVENQAKRLLEQGLETQNPTQVGTALQVFYNLGTLKDTITS VVDGYCATLEENINSALDIKVLTQPSQSAVRGGPGRSTMPTPGNTA ALRASFWTNMEKLMDHIYAVCGQVQHLQKVLAKKRDPVSHICFIE EIVKDGQPEIFYTFWNSVTQALSSQFHMATNSSMFLKQAFEGEYPK LLRLYNDLWKRLQQYSQHIQGNFNASGTTDLYVDLQHMEDDAQDI FIPKKPDYDPEKALKDSLQPYEAAYLSKSLSRLFDPINLVFPPGGRNP PSSDELDGIIKTIASELNVAAVDTNLTLAVSKNVAKTIQLYSVKSEQL LSTQGDASQVIGPLTEGQRRNVAVVNSLYKLHQSVTKAIHALMENA VQPLLTSVGDAIEAIIITMHQEDFSGSLSSSGKPDVPCSLYMKELQGF IARVMSDYFKHFECLDFVFDNTEAIAQRAVELFIRHASLIRPLGEGG KMRLAADFAQMELAVGPFCRRVSDLGKSYRMLRSFRPLLFQASEH VASSPALGDVIPFSIIIQFLFTRAPAELKSPFQRAEWSHTRFSQWLDD HPSEKDRLLLIRGALEAYVQSVRSREGKEFAPVYPIMVQLLQKAMS ALQ 210 MAEGSGEVVAVSATGAANGLNNGAGGTSATTCNPLSRKLHKILET COG6 RLDNDKEMLEALKALSTFFVENSLRTRRNLRGDIERKSLAINEEFVSI FKEVKEELESISEDVQAMSNCCQDMTSRLQAAKEQTQDLIVKTTKL QSESQKLEIRAQVADAFLSKFQLTSDEMSLLRGTREGPITEDFFKAL GRVKQIHNDVKVLLRTNQQTAGLEIMEQMALLQETAYERLYRWAQ SECRTLTQESCDVSPVLTQAMEALQDRPVLYKYTLDEFGTARRSTV VRGFIDALTRGGPGGTPRPIEMHSHDPLRYVGDMLAWLHQATASE KEHLEALLKHVTTQGVEENIQEVVGHITEGVCRPLKVRIEQVIVAEP GAVLLYKISNLLKFYHHTISGIVGNSATALLTTIEEMHLLSKKIFFNS LSLHASKLMDKVELPPPDLGPSSALNQTLMLLREVLASHDSSVVPL DARQADFVQVLSCVLDPLLQMCTVSASNLGTADMATFMVNSLYM MKTTLALFEFTDRRLEMLQFQIEAHLDTLINEQASYVLTRVGLSYIY NTVQQHKPEQGSLANMPNLDSVTLKAAMVQFDRYLSAPDNLLIPQ LNFLLSATVKEQIVKQSTELVCRAYGEVYAAVMNPINEYKDPENIL HRSPQQVQTLLS 211 MDFSKFLADDFDVKEWINAAFRAGSKEAASGKADGHAATLVMKL COG7 QLFIQEVNHAVEETSHQALQNMPKVLRDVEALKQEASFLKEQMILV KEDIKKFEQDTSQSMQVLVEIDQVKSRMQLAAESLQEADKWSTLSA DIEETFKTQDIAVISAKLTGMQNSLMMLVDTPDYSEKCVHLEALKN RLEALASPQIVAAFTSQAVDQSKVFVKVFTEIDRMPQLLAYYYKCH KVQLLAAWQELCQSDLSLDRQLTGLYDALLGAWHTQIQWATQVF QKPHEVVMVLLIQTLGALMPSLPSCLSNGVERAGPEQELTRLLEFY DATAHFAKGLEMALLPHLHEHNLVKVTELVDAVYDPYKPYQLKY GDMEESNLLIQMSAVPLEHGEVIDCVQELSHSVNKLFGLASAAVDR CVRFTNGLGTCGLLSALKSLFAKYVSDFTSTLQSIRKKCKLDHIPPNS LFQEDWTAFQNSIRIIATCGELLRHCGDFEQQLANRILSTAGKYLSDS CSPRSLAGFQESILTDKKNSAKNPWQEYNYLQKDNPAEYASLMEIL YTLKEKGSSNHNLLAAPRAALTRLNQQAHQLAFDSVFLRIKQQLLLI SKMDSWNTAGIGETLTDELPAFSLTPLEYISNIGQYIMSLPLNLEPFV TQEDSALELALHAGKLPFPPEQGDELPELDNMADNWLGSIARATM QTYCDAILQIPELSPHSAKQLATDIDYLINVMDALGLQPSRTLQHIVT LLKTRPEDYRQVSKGLPRRLATTVATMRSVNY 212 MATAATIPSVATATAAALGEVEDEGLLASLFRDRFPEAQWRERPDV COG8 GRYLRELSGSGLERLRREPERLAEERAQLLQQTRDLAFANYKTFIRG AECTERIHRLFGDVEASLGRLLDRLPSFQQSCRNFVKEAEEISSNRR MNSLTLNRHTEILEILEIPQLMDTCVRNSYYEEALELAAYVRRLERK YSSIPVIQGIVNEVRQSMQLMLSQLIQQLRTNIQLPACLRVIGYLRRM DVFTEAELRVKFLQARDAWLRSILTAIPNDDPYFHITKTIEASRVHLF DIITQYRAIFSDEDPLLPPAMGEHTVNESAIFHGWVLQKVSQFLQVL ETDLYRGIGGHLDSLLGQCMYFGLSFSRVGADFRGQLAPVFQRVAI STFQKAIQETVEKFQEEMNSYMLISAPAILGTSNMPAAVPATQPGTL QPPMVLLDFPPLACFLNNILVAFNDLRLCCPVALAQDVTGALEDAL AKVTKIILAFHRAEEAAFSSGEQELFVQFCTVFLEDLVPYLNRCLQV LFPPAQIAQTLGIPPTQLSKYGNLGHVNIGAIQEPLAFILPKRETLFTL DDQALGPELTAPAPEPPAEEPRLEPAGPACPEGGRAETQAEPPSVGP 213 DRLLQQGSAVFQFRMSANSGLLPASMVMPLLGLVMKERCQTAGNP DOLK FFERFGIVVAATGMAVALFSSVLALGITRPVPTNTCVILGLAGGVIIY IMKHSLSVGEVIEVLEVLLIFVYLNMILLYLLPRCFTPGEALLVLGGI SFVLNQLIKRSLTLVESQGDPVDFFLLVVVVGMVLMGIFFSTLFVFM DSGTWASSIFFHLMTCVLSLGVVLPWLHRLIRRNPLLWLLQFLFQTD TRIYLLAYWSLLATLACLVVLYQNAKRSSSESKKHQAPTIARKYFH LIVVATYIPGIIFDRPLLYVAATVCLAVFIFLEYVRYFRIKPLGHTLRS FLSLFLDERDSGPLILTHIYLLLGMSLPIWLIPRPCTQKGSLGGARAL VPYAGVLAVGVGDTVASIFGSTMGEIRWPGTKKTFEGTMTSIFAQII SVALILIFDSGVDLNYSYAWILGSISTVSLLEAYTTQIDNLLLPLYLLI LLMA 214 MSWIKEGELSLWERFCANIIKAGPMPKHIAFIMDGNRRYAKKCQVE DHDDS RQEGHSQGFNKLAETLRWCLNLGILEVTVYAFSIENFKRSKSEVDGL MDLARQKFSRLMEEKEKLQKHGVCIRVLGDLHLLPLDLQELIAQAV QATKNYNKCFLNVCFAYTSRHEISNAVREMAWGVEQGLLDPSDISE SLLDKCLYTNRSPHPDILIRTSGEVRLSDFLLWQTSHSCLVFQPVLW PEYTFWNLFEAILQFQMNHSVLQKARDMYAEERKRQQLERDQATV TEQLLREGLQASGDAQLRRTRLHKLSARREERVQGFLQALELKRAD WLARLGTASA 215 MWAFSELPMPLLINLIVSLLGFVATVTLIPAFRGHFIAARLCGQDLN DPAGT1 KTSRQQIPESQGVISGAVFLIILFCFIPFPFLNCFVKEQCKAFPHHEFV ALIGALLAICCMIFLGFADDVLNLRWRHKLLLPTAASLPLLMVYFTN FGNTTIVVPKPFRPILGLHLDLGILYYVYMGLLAVFCTNAINILAGIN GLEAGQSLVISASIIVFNLVELEGDCRDDHVFSLYFMIPFFFTTLGLL YHNWYPSRVFVGDTFCYFAGMTFAVVGILGHFSKTMLLFFMPQVF NFLYSLPQLLHIIPCPRHRIPRLNIKTGKLEMSYSKFKTKSLSFLGTFIL KVAESLQLVTVHQSETEDGEFTECNNMTLINLLLKVLGPIHERNLTL LLLLLQILGSAITFSIRYQLVRLFYDV 216 MASLEVSRSPRRSRRELEVRSPRQNKYSVLLPTYNERENLPLIVWLL DPM1 VKSFSESGINYEIIIIDDGSPDGTRDVAEQLEKIYGSDRILLRPREKKL GLGTAYIHGMKHATGNYIIIMDADLSHHPKFIPEFIRKQKEGNFDIVS GTRYKGNGGVYGWDLKRKIISRGANFLTQILLRPGASDLTGSFRLY RKEVLEKLIEKCVSKGYVFQMEMIVRARQLNYTIGEVPISFVDRVY GESK LGGNEIVSFLKGLLTLFATT 217 MATGTDQVVGLGLVAVSLIIFTYYTAWVILLPFIDSQHVIHKYFLPR DPM2 AYAVAIPLAAGLLLLLFVGLFISYVMLKTKRVTKKAQ 218 MTKLAQWLWGLAILGSTWVALTTGALGLELPLSCQEVLWPLPAYL DPM3 LVSAGCYALGTVGYRVATFHDCEDAARELQSQIQEARADLARRGL RF 219 MESTLGAGIVIAEALQNQLAWLENVWLWITFLGDPKILFLFYFPAAY G6PC3 YASRRVGIAVLWISLITEWLNLIFKWFLFGDRPFWWVHESGYYSQA PAQVHQFPSSCETGPGSPSGHCMITGAALWPIMTALSSQVATRARSR WVRVMPSLAYCTFLLAVGLSRIFILAHFPHQVLAGLITGAVLGWLM TPRVPMERELSFYGLTALALMLGTSLIYWTLFTLGLDLSWSISLAFK WCERPEWIHVDSRPFASLSRDSGAALGLGIALHSPCYAQVRRAQLG NGQKIACLVLAMGLLGPLDWLGHPPQISLFYIFNFLKYTLWPCLVL ALVPWAVHMFSAQEAPPIHSS 220 MCGIFAYLNYHVPRTRREILETLIKGLQRLEYRGYDSAGVGFDGGN GFPT1 DKDWEANACKIQLIKKKGKVKALDEEVHKQQDMDLDIEFDVHLGI AHTRWATHGEPSPVNSHPQRSDKNNEFIVIHNGIITNYKDLKKFLES KGYDFESETDTETIAKLVKYMYDNRESQDTSFTTLVERVIQQLEGAF ALVFKSVHFPGQAVGTRRGSPLLIGVRSEHKLSTDHIPILYRTARTQI GSKFTRWGSQGERGKDKKGSCNLSRVDSTTCLFPVEEKAVEYYFAS DASAVIEHTNRVIFLEDDDVAAVVDGRLSIHRIKRTAGDHPGRAVQ TLQMELQQIMKGNFSSFMQKEIFEQPESVVNTMRGRVNFDDYTVNL GGLKDHIKEIQRCRRLILIACGTSYHAGVATRQVLEELTELPVMVEL ASDFLDRNTPVFRDDVCFFLSQSGETADTLMGLRYCKERGALTVGI TNTVGSSISRETDCGVHINAGPEIGVASTKAYTSQFVSLVMFALMM CDDRISMQERRKEIMLGLKRLPDLIKEVLSMDDEIQKLATELYHQKS VLIMGRGYHYATCLEGALKIKEITYMHSEGILAGELKHGPLALVDK LMPVIMIIMRDHTYAKCQNALQQVVARQGRPVVICDKEDTETIKNT KRTIKVPHSVDCLQGILSVIPLQLLAFHLAVLRGYDVDFPRNLAKSV TVE 221 MLKAVILIGGPQKGTRFRPLSFEVPKPLFPVAGVPMIQHHIEACAQV GMPPA PGMQEILLIGFYQPDEPLTQFLEAAQQEFNLPVRYLQEFAPLGTGGG LYHFRDQILAGSPEAFFVLNADVCSDFPLSAMLEAHRRQRHPFLLLG TTANRTQSLNYGCIVENPQTHEVLHYVEKPSTFISDIINCGIYLFSPEA LKPLRDVFQRNQQDGQLEDSPGLWPGAGTIRLEQDVFSALAGQGQI YVHL TDGIWSQIKSAGSALYASRLYLSRYQDTHPERLAKHTPGGPWIRGN VYIHPTAKVAPSAVLGPNVSIGKGVTVGEGVRLRESIVLHGATLQEH TCVLHSIVGWGSTVGRWARVEGTPSDPNPNDPRARMDSESLFKDG KLLPAITILGCRVRIPAEVLILNSIVLPHKELSRSFTNQIIL 222 MKALILVGGYGTRLRPLTLSTPKPLVDFCNKPILLHQVEALAAAGV GMPPB DHVILAVSYMSQVLEKEMKAQEQRLGIRISMSHEEEPLGTAGPLAL ARDLLSETADPFFVLNSDVICDFPFQAMVQFHRHHGQEGSILVTKVE EPSKYGVVVCEADTGRIHRFVEKPQVFVSNKINAGMYILSPAVLQRI QLQPTSIEKEVFPIMAKEGQLYAMELQGFWMDIGQPKDFLTGMCLF LQSLRQKQPERLCSGPGIVGNVLVDPSARIGQNCSIGPNVSLGPGVV VEDGVCIRRCTVLRDARIRSHSWLESCIVGWRCRVGQWVRMENVT VLGEDVIVNDELYLNGASVLPHKSIGESVPEPRIIM 223 MAARWRFWCVSVTMVVALLIVCDVPSASAQRKKEMVLSEKVSQL MAGT1 MEWTNKRPVIRMNGDKFRRLVKAPPRNYSVIVMFTALQLHRQCVV CKQADEEFQILANSWRYSSAFTNRIFFAMVDFDEGSDVFQMLNMNS APTFINFPAKGKPKRGDTYELQVRGFSAEQIARWIADRTDVNIRVIR PPNYAGPLMLGLLLAVIGGLVYLRRSNMEFLFNKTGWAFAALCFVL AMTSGQMWNHIRGPPYAHKNPHTGHVNYIHGSSQAQFVAETHIVL LFNGGVTLGMVLLCEAATSDMDIGKRKIMCVAGIGLVVLFFSWML SIFRSKYHGYPYSFLMS 224 MAACEGRRSGALGSSQSDFLTPPVGGAPWAVATTVVMYPPPPPPPH MAN1B1 RDFISVTLSFGENYDNSKSWRRRSCWRKWKQLSRLQRNMILFLLAF LLFCGLLFYINLADHWKALAFRLEEEQKMRPEIAGLKPANPPVLPAP QKADTDPENLPEISSQKTQRHIQRGPPHLQIRPPSQDLKDGTQEEAT KRQEAPVDPRPEGDPQRTVISWRGAVIEPEQGTELPSRRAEVPTKPP LPPARTQGTPVHLNYRQKGVIDVFLHAWKGYRKFAWGHDELKPVS RSFSEWFGLGLTLIDALDTMWILGLRKEFEEARKWVSKKLHFEKDV DVNLFESTIRILGGLLSAYHLSGDSLFLRKAEDFGNRLMPAFRTPSKI PYSDVNIGTGVAHPPRWTSDSTVAEVTSIQLEFRELSRLTGDKKFQE AVEKVTQHIHGLSGKKDGLVPMFINTHSGLFTHLGVFTLGARADSY YEYLLKQWIQGGKQETQLLEDYVEAIEGVRTHLLRHSEPSKLTFVG ELAHGRFSAKMDHLVCFLPGTLALGVYHGLPASHMELAQELMETC YQMNRQMETGLSPEIVHFNLYPQPGRRDVEVKPADRHNLLRPETVE SLFYLYRVTGDRKYQDWGWEILQSFSRFTRVPSGGYSSINNVQDPQ KPEPRDKMESFFLGETLKYLFLLFSDDPNLLSLDAYVFNTEAHPLPI WTPA 225 MRFRIYKRKVLILTLVVAACGFVLWSSNGRQRKNEALAPPLLDAEP MGAT2 ARGAGGRGGDHPSVAVGIRRVSNVSAASLVPAVPQPEADNLTLRY RSLVYQLNFDQTLRNVDKAGTWAPRELVLVVQVHNRPEYLRLLLD SLRKAQGIDNVLVIFSHDFWSTEINQLIAGVNFCPVLQVFFPFSIQLY PNEFPGSDPRDCPRDLPKNAALKLGCINAEYPDSFGHYREAKFSQTK HHWWWKLHFVWERVKILRDYAGLILFLEEDHYLAPDFYHVFKKM WKLKQQECPECDVLSLGTYSASRSF YGMADKVDVKTWKSTEHNMGLALTRNAYQKLIECTDTFCTYDDY NWDWTLQYLTVSCLPKFWKVLVPQIPRIFHAGDCGMHHKKTCRPS TQSAQIESLLNNNKQYMFPETLTISEKFTVVAISPPRKNGGWGDIRD HELCKSYRRLQ 226 MARGERRRRAVPAEGVRTAERAARGGPGRRDGRGGGPRSTAGGV MOGS ALAVVVLSLALGMSGRWVLAWYRARRAVTLHSAPPVLPADSSSPA VAPDLFWGTYRPHVYFGMKTRSPKPLLTGLMWAQQGTTPGTPKLR HTCEQGDGVGPYGWEFHDGLSFGRQHIQDGALRLTTEFVKRPGGQ HGGDWSWRVTVEPQDSGTSALPLVSLFFYVVTDGKEVLLPEVGAK GQLKFISGHTSELGDFRFTLLPPTSPGDTAPKYGSYNVFWTSNPGLP LLTEMVKSRLNSWFQHRPPGAPPERYLGLPGSLKWEDRGPSGQGQ GQFLIQQVTLKIPISIEFVFESGSAQAGGNQALPRLAGSLLTQALESH AEGFRERFEKTFQLKEKGLSSGEQVLGQAALSGLLGGIGYFYGQGL VLPDIGVEGSEQKVDPALFPPVPLFTAVPSRSFFPRGFLWDEGFHQL VVQRWDPSLTREALGHWLGLLNADGWIGREQILGDEARARVPPEF LVQRAVHANPPTLLLPVAHMLEVGDPDDLAFLRKALPRLHAWFSW LHQSQAGPLPLSYRWRGRDPALPTLLNPKTLPSGLDDYPRASHPSVT ERHLDLRCWVALGARVLTRLAEHLGEAEVAAELGPLAASLEAAES LDELHWAPELGVFADFGNHTKAVQLKPRPPQGLVRVVGRPQPQLQ YVDALGYVSLFPLLLRLLDPTSSRLGPLLDILADSRHLWSPFGLRSL AASSSFYGQRNSEHDPPYWRGAVWLNVNYLALGALHHYGHLEGP HQARAAKLHGELRANVVGNVWRQYQATGFLWEQYSDRDGRGMG CRPFHGWTSLVLLAMAEDY 227 MAAEADGPLKRLLVPILLPEKCYDQLFVQWDLLHVPCLKILLSKGL MPDU1 GLGIVAGSLLVKLPQVFKILGAKSAEGLSLQSVMLELVALTGTMVY SITNNFPFSSWGEALFLMLQTITICFLVMHYRGQTVKGVAFLACYGL VLLVLLSPLTPLTVVTLLQASNVPAVVVGRLLQAATNYHNGHTGQL SAITVFLLFGGSLARIFTSIQETGDPLMAGTFVVSSLCNGLIAAQLLF YWNAKPPHKQKKAQ 228 MAAPRVFPLSCAVQQYAWGKMGSNSEVARLLASSDPLAQIAEDKP MPI YAELWMGTHPRGDAKILDNRISQKTLSQWIAENQDSLGSKVKDTFN GNLPFLFKVLSVETPLSIQAHPNKELAEKLHLQAPQHYPDANHKPE MAIALTPFQGLCGFRPVEEIVTFLKKVPEFQFLIGDEAATHLKQTMS HDSQAVASSLQSCFSHLMKSEKKVVVEQLNLLVKRISQQAAAGNN MEDIFGELLLQLHQQYPGDIGCFAIYFLNLLTLKPGEAMFLEANVPH AYLKGDCVECMACSDNTVRAGLTP KFIDVPTLCEMLSYTPSSSKDRLFLPTRSQEDPYLSIYDPPVPDFTIMK TEVPGSVTEYKVLALDSASILLMVQGTVIASTPTTQTPIPLQRGGVLF IGANESVSLKLTEPKDLLIFRACCLL 229 MAAAALGSSSGSASPAVAELCQNTPETFLEASKLLLTYADNILRNPN NGLY1 DEKYRSIRIGNTAFSTRLLPVRGAVECLFEMGFEEGETHLIFPKKASV EQLQKIRDLIAIERSSRLDGSNKSHKVKSSQQPAASTQLPTTPSSNPS GLNQHTRNRQGQSSDPPSASTVAADSAILEVLQSNIQHVLVYENPAL QEKALACIPVQELKRKSQEKLSRARKLDKGINISDEDFLLLELLHWF KEE FFHWVNNVLCSKCGGQTRSRDRSLLPSDDELKWGAKEVEDHYCDA CQFSNRFPRYNNPEKLLETRCGRCGEWANCFTLCCRAVGFEARYV WDYTDHVWTEVYSPSQQRWLHCDACEDVCDKPLLYEIGWGKKLS YVIAFSKDEVVDVTWRYSCKHEEVIARRTKVKEALLRDTINGLNKQ RQLFLSENRRKELLQRIIVELVEFISPKTPKPGELGGRISGSVAWRVA RGEMGLQRKETLFIPCENEKISKQLHLCYNIVKDRYVRVSNNNQTIS GWENGVWKMESIFRKVETDWHMVYLARKEGSSFAYISWKFECGS VGLKVDSISIRTSSQTFQTGTVEWKLRSDTAQVELTGDNSLHSYADF SGATEVILEAELSRGDGDVAWQHTQLFRQSLNDHEENCLEIIIKFSDL 230 MVKIVTVKTQAYQDQKPGTSGLRKRVKVFQSSANYAENFIQSIISTV PGM1 EPAQRQEATLVVGGDGRFYMKEAIQLIARIAAANGIGRLVIGQNGIL STPAVSCIIRKIKAIGGIILTASHNPGGPNGDFGIKFNISNGGPAPEAIT DKIFQISKTIEEYAVCPDLKVDLGVLGKQQFDLENKFKPFTVEIVDS VEAYATMLRSIFDFSALKELLSGPNRLKIRIDAMHGVVGPYVKKILC EELGAPANSAVNCVPLEDFGGHHPDPNLTYAADLVETMKSGEHDF GAAFDGDGDRNMILGKHGFFVNPSDSVAVIAANIFSIPYFQQTGVRG FARSMPTSGALDRVASATKIALYETPTGWKFFGNLMDASKLSLCGE ESFGTGSDHIREKDGLWAVLAWLSILATRKQSVEDILKDHWQKYGR NFFTRYDYEEVEAEGANKMMKDLEALMFDRSFVGKQFSANDKVY TVEKADNFEYSDPVDGSISRNQGLRLIFTDGSRIVFRLSGTGSAGATI RLYIDSYEKDVAKINQDPQVMLAPLISIALKVSQLQERTGRTAPTVIT 231 MDLGAITKYSALHAKPNGLILQYGTAGFRTKAEHLDHVMFRMGLL PGM3 AVLRSKQTKSTIGVMVTASHNPEEDNGVKLVDPLGEMLAPSWEEH ATCLANAEEQDMQRVLIDISEKEAVNLQQDAFVVIGRDTRPSSEKLS QSVIDGVTVLGGQFHDYGLLTTPQLHYMVYCRNTGGRYGKATIEG YYQKLSKAFVELTKQASCSGDEYRSLKVDCANGIGALKLREMEHY FSQGLSVQLFNDGSKGKLNHLCGADFVKSHQKPPQGMEIKSNERCC SFDGDADRIVYYYHDADGHFHLIDGDKIATLISSFLKELLVEIGESLN IGVVQTAYANGSSTRYLEEVMKVPVYCTKTGVKHLHHKAQEFDIG VYFEANGHGTALFSTAVEMKIKQSAEQLEDKKRKAAKMLENIIDLF NQAAGDAISDMLVIEAILALKGLTVQQWDALYTDLPNRQLKVQVA DRRVISTTDAERQAVTPPGLQEAINDLVKKYKLSRAFVRPSGTEDV VRVYAEADSQESADHLAHEVSLAVFQLAGGIGERPQPGF 232 MGSQEVLGHAARLASSGLLLQVLFRLITFVLNAFILRFLSKEIVGVV RFT1 NVRLTLLYSTTLFLAREAFRRACLSGGTQRDWSQTLNLLWLTVPLG VFWSLFLGWIWLQLLEVPDPNVVPHYATGVVLFGLSAVVELLGEPF WVLAQAHMFVKLKVIAESLSVILKSVLTAFLVLWLPHWGLYIFSLA QLFYTTVLVLCYVIYFTKLLGSPESTKLQTLPVSRITDLLPNITRNGA FINWKEAKLTWSFFKQSFLKQILTEGERYVMTFLNVLNFGDQGVYD IVNNLGSLVARLIFQPIEESFYIFFAKVLERGKDATLQKQEDVAVAA AVLESLLKLALLAGLTITVFGFAYSQLALDIYGGTMLSSGSGPVLLR SYCLYVLLLAINGVTECFTFAAMSKEEVDRYNFVMLALSSSFLVLS YLLTRWCGSVGFILANCFNMGIRITQSLCFIHRYYRRSPHRPLAGLH LSPVLLGTFALSGGVTAVSEVFLCCEQGWPARLAHIAVGAFCLGAT LGTAFLTETKLIHFLRTQLGVPRRTDKMT 233 MATYLEFIQQNEERDGVRFSWNVWPSSRLEATRMVVPLACLLTPLK SEC23B ERPDLPPVQYEPVLCSRPTCKAVLNPLCQVDYRAKLWACNFCFQRN QFPPAYGGISEVNQPAELMPQFSTIEYVIQRGAQSPLIFLYVVDTCLE EDDLQALKESLQMSLSLLPPDALVGLITFGRMVQVHELSCEGISKSY VFRGTKDLTAKQIQDMLGLTKPAMPMQQARPAQPQEHPFASSRFL QPVHKIDMNLTDLLGELQRDPWPVTQGKRPLRSTGVALSIAVGLLE GTFPNTGARIMLFTGGPPTQGPGMVVGDELKIPIRSWHDIEKDNARF MKKATKHYEMLANRTAANGHCIDIYACALDQTGLLEMKCCANLT GGYMVMGDSFNTSLFKQTFQRIFTKDFNGDFRMAFGATLDVKTSR ELKIAGAIGPCVSLNVKGPCVSENELGVGGTSQWKICGLDPTSTLGI YFEVVNQHNTPIPQGGRGAIQFVTHYQHSSTQRRIRVTTIARNWAD VQSQLRHIEAAFDQEAAAVLMARLGVFRAESEEGPDVLRWLDRQLI RLCQKFGQYNKEDPTSFRLSDSFSLYPQFMFHLRRSPFLQVFNNSPD ESSYYRHHFARQDLTQSLIMIQPILYSYSFHGPPEPVLLDSSSILADRI LLMDTFFQIVIYLGETIAQWRKAGYQDMPEYENFKHLLQAPLDDAQ EILQARFPMPRYINTEHGGSQARFLLSKVNPSQTHNNLYAWGQETG APILTDDVSLQVFMDHLKKLAVSSAC 234 MAAPRDNVTLLFKLYCLAVMTLMAAVYTIALRYTRTSDKELYFST SLC35A1 TAVCITEVIKLLLSVGILAKETGSLGRFKASLRENVLGSPKELLKLSV PSLVYAVQNNMAFLALSNLDAAVYQVTYQLKIPCTALCTVLMLNR TLSKLQWVSVFMLCAGVTLVQWKPAQATKVVVEQNPLLGFGAIAI AVLCSGFAGVYFEKVLKSSDTSLWVRNIQMYLSGIIVTLAGVYLSD GAEIKEKGFFYGYTYYVWFVIFLASVGGLYTSVVVKYTDNIMKGFS AAAAIVLSTIASVMLFGLQITLTFALGTLLVCVSIYLYGLPRQDTTSI QQGETASKERVIGV 235 MAAVGAGGSTAAPGPGAVSAGALEPGTASAAHRRLKYISLAVLVV SLC35A2 QNASLILSIRYARTLPGDRFFATTAVVMAEVLKGLTCLLLLFAQKRG NVKHLVLFLHEAVLVQYVDTLKLAVPSLIYTLQNNLQYVAISNLPA ATFQVTYQLKILTTALFSVLMLNRSLSRLQWASLLLLFTGVAIVQAQ QAGGGGPRPLDQNPGAGLAAVVASCLSSGFAGVYFEKILKGSSGSV WLRNLQLGLFGTALGLVGLWWAEGTAVATRGFFFGYTPAVWGVV LNQAFGGLLVAVVVKYADNILKGFATSLSIVLSTVASIRLFGFHVDP LFALGAGLVIGAVYLYSLPRGAAKAIASASASASGPCVHQQPPGQPP PPQLSSHRGDLITEPFLPKLLTKVKGS 236 MNRAPLKRSRILHMALTGASDPSAEAEANGEKPFLLRALQIALVVS SLC35C1 LYWVTSISMVFLNKYLLDSPSLRLDTPIFVTFYQCLVTTLLCKGLSA LAACCPGAVDFPSLRLDLRVARSVLPLSVVFIGMITFNNLCLKYVGV AFYNVGRSLTTVFNVLLSYLLLKQTTSFYALLTCGIIIGGFWLGVDQ EGAEGTLSWLGTVFGVLASLCVSLNAIYTTKVLPAVDGSIWRLTFY NNVNACILFLPLLLLLGELQALRDFAQLGSAHFWGMMTLGGLFGFA IGYVTGLQIKFTSPLTHNVSG TAKACAQTVLAVLYYEETKSFLWWTSNMMVLGGSSAYTWVRGW EMKKTPEEPSPKDSEKSAMGV 237 MAAMASLGALALLLLSSLSRCSAEACLEPQITPSYYTTSDAVISTET SSR4 VFIVEISLTCKNRVQNMALYADVGGKQFPVTRGQDVGRYQVSWSL DHKSAHAGTYEVRFFDEESYSLLRKAQRNNEDISIIPPLFTVSVDHR GTWNGPWVSTEVLAAAIGLVIYYLAFSAKSHIQA 238 MAPWAEAEHSALNPLRAVWLTLTAAFLLTLLLQLLPPGLLPGCAIF SRD5A3 QDLIRYGKTKCGEPSRPAACRAFDVPKRYFSHFYIISVLWNGFLLWC LTQSLFLGAPFPSWLHGLLRILGAAQFQGGELALSAFLVLVFLWLHS LRRLFECLYVSVFSNVMIHVVQYCFGLVYYVLVGLTVLSQVPMDG RNAYITGKNLLMQARWFHILGMMMFIWSSAHQYKCHVILGNLRKN KAGVVIHCNHRIPFGDWFEYVSSPNYLAELMIYVSMAVTFGFHNLT WWLVVTNVFFNQALSAFLSHQFYKSKFVSYPKHRKAFLPFLF 239 MAAAAPGNGRASAPRLLLLFLVPLLWAPAAVRAGPDEDLSHRNKE TMEM165 PPAPAQQLQPQPVAVQGPEPARVEKIFTPAAPVHTNKEDPATQTNL GFIHAFVAAISVIIVSELGDKTFFIAAIMAMRYNRLTVLAGAMLALG LMTCLSVLFGYATTVIPRVYTYYVSTVLFAIFGIRMLREGLKMSPDE GQEELEEVQAELKKKDEEFQRTKLLNGPGDVETGTSITVPQKKWLH FISPIFVQALTLTFLAEWGDRSQLTTIVLAAREDPYGVAVGGTVGHC LCTGLAVIGGRMIAQKISVRTVTIIGGIVFLAFAFSALFISPDSGF 240 MSSWLGGLGSGLGQSLGQVGGSLASLTGQISNFTKDMLMEGTEEV TRIP11 EAELPDSRTKEIEAIHAILRSENERLKKLCTDLEEKHEASEIQIKQQST SYRNQLQQKEVEISHLKARQIALQDQLLKLQSAAQSVPSGAGVPAT TASSSFAYGISHHPSAFHDDDMDFGDIISSQQEINRLSNEVSRLESEV GHWRHIAQTSKAQGTDNSDQSEICKLQNIIKELKQNRSQEIDDHQHE MSVLQNAHQQKLTEISRRHREELSDYEERIEELENLLQQGGSGVIET DLSKIYEMQKTIQVLQIEKVESTKKMEQLEDKIKDINKKLSSAENDR DILRREQEQLNVEKRQIMEECENLKLECSKLQPSAVKQSDTMTEKE RILAQSASVEEVFRLQQALSDAENEIMRLSSLNQDNSLAEDNLKLK MRIEVLEKEKSLLSQEKEELQMSLLKLNNEYEVIKSTATRDISLDSEL HDLRLNLEAKEQELNQSISEKETLIAEIEELDRQNQEATKHMILIKDQ LSKQQNEGDSIISKLKQDLNDEKKRVHQLEDDKMDITKELDVQKEK LIQSEVALNDLHLTKQKLEDKVENLVDQLNKSQESNVSIQKENLEL KEHIRQNEEELSRIRNELMQSLNQDSNSNFKDTLLKEREAEVRNLKQ NLSELEQLNENLKKVAFDVKMENEKLVLACEDVRHQLEECLAGNN QLSLEKNTIVETLKMEKGEIEAELCWAKKRLLEEANKYEKTIEELSN ARNLNTSALQLEHEHLIKLNQKKDMEIAELKKNIEQMDTDHKETKD VLSSSLEEQKQLTQLINKKEIFIEKLKERSSKLQEELDKYSQALRKNE ILRQTIEEKDRSLGSMKEENNHLQEELERLREEQSRTAPVADPKTLD SVTELASEVSQLNTIKEHLEEEIKHHQKIIEDQNQSKMQLLQSLQEQ KKEMDEFRYQHEQMNATHTQLFLEKDEEIKSLQKTIEQIKTQLHEER QDIQTDNSDIFQETKVQSLNIENGSEKHDLSKAETERLVKGIKERELE IKLLNEKNISLTKQIDQLSKDEVGKLTQIIQQKDLEIQALHARISSTSH TQDVVYLQQQLQAYAMEREKVFAVLNEKTRENSHLKTEYHKMMD IVAAKEAALIKLQDENKKLSTRFESSGQDMFRETIQNLSRIIREKDIEI DALSQKCQTLLAVLQTSSTGNEAGGVNSNQFEELLQERDKLKQQV KKMEEWKQQVMTTVQNMQHESAQLQEELHQLQAQVLVDSDNNS KLQVDYTGLIQSYEQNETKLKNFGQELAQVQHSIGQLCNTKDLLLG KLDIISPQLSSASLLTPQSAECLRASKSEVLSESSELLQQELEELRKSL QEKDATIRTLQENNHRLSDSIAATSELERKEHEQTDSEIKQLKEKQD VLQKLLKEKDLLIKAKSDQLLSSNENFTNKVNENELLRQAVTNLKE RILILEMDIGKLKGENEKIVETYRGKETEYQALQETNMKFSMMLRE KEFECHSMKEKALAFEQLLKEKEQGKTGELNQLLNAVKSMQEKTV VFQQERDQVMLALKQKQMENTALQNEVQRLRDKEFRSNQELERLR NHLLESEDSYTREALAAEDREAKLRKKVTVLEEKLVSSSNAMENAS HQASVQVESLQEQLNVVSKQRDETALQLSVSQEQVKQYALSLANL QMVLEHFQQEEKAMYSAELEKQKQLIAEWKKNAENLEGKVISLQE CLDEANAALDSASRLTEQLDVKEEQIEELKRQNELRQEMLDDVQK KLMSLANSSEGKVDKVLMRNLFIGHFHTPKNQRHEVLRLMGSILGV RREEMEQLFHDDQGGVTRWMTGWLGGGSKSVPNTPLRPNQQSVV NSSFSELFVKFLETESHPSIPPPKLSVHDMKPLDSPGRRKRDTNAPES FKDTAESRSGRRTDVNPFLAPRSAAVPLINPAGLGPGGPGHLLLKPIS DVLPTFTPLPALPDNSAGVVLKDLLKQ 241 MGARGAPSRRRQAGRRLRYLPTGSFPFLLLLLLLCIQLGGGQKKKE TUSC3 NLLAEKVEQLMEWSSRRSIFRMNGDKFRKFIKAPPRNYSMIVMFTA LQPQRQCSVCRQANEEYQILANSWRYSSAFCNKLFFSMVDYDEGT DVFQQLNMNSAPTFMHFPPKGRPKRADTFDLQRIGFAAEQLAKWIA DRTDVHIRVFRPPNYSGTIALALLVSLVGGLLYLRRNNLEFIYNKTG WAMVSLCIVFAMTSGQMWNHIRGPPYAHKNPHNGQVSYIHGSSQA QFVAESHIILVLNAAITMGMVLLNE AATSKGDVGKRRIICLVGLGLVVFFFSFLLSIFRSKYHGYPYSDLDFE 242 MVCVLVLAAAAGAVAVFLILRIWVVLRSMDVTPRESLSILVVAGSG ALG14 GHTTEILRLLGSLSNAYSPRHYVIADTDEMSANKINSFELDRADRDP SNMYTKYYIHRIPRSREVQQSWPSTVFTTLHSMWLSFPLIHRVKPDL VLCNGPGTCVPICVSALLLGILGIKKVIIVYVESICRVETLSMSGKILF HLSDYFIVQWPALKEKYPKSVYLGRIV 243 MRLREPLLSGSAAMPGASLQRACRLLVAVCALHLGVTLVYYLAGR B4GALT1 DLSRLPQLVGVSTPLQGGSNSAAAIGQSSGELRTGGARPPPPLGASS QPRPGGDSSPVVDSGPGPASNLTSVPVPHTTALSLPACPEESPLLVGP MLIEFNMPVDLELVAKQNPNVKMGGRYAPRDCVSPHKVAIIIPFRN RQEHLKYWLYYLHPVLQRQQLDYGIYVINQAGDTIFNRAKLLNVGF QEALKDYDYTCFVFSDVDLIPMNDHNAYRCFSQPRHISVAMDKFGF SLPYVQYFGGVSALSKQQFLTINGFPNNYWGWGGEDDDIFNRLVFR GMSISRPNAVVGRCRMIRHSRDKKNEPNPQRFDRIAHTKETMLSDG LNSLTYQVLDVQRYPLYTQITVDIGTPS 244 MGYFRCARAGSFGRRRKMEPSTAARAWALFWLLLPLLGAVCASGP DDOST RTLVLLDNLNVRETHSLFFRSLKDRGFELTFKTADDPSLSLIKYGEFL YDNLIIFSPSVEDFGGNINVETISAFIDGGGSVLVAASSDIGDPLRELG SECGIEFDEEKTAVIDHHNYDISDLGQHTLIVADTENLLKAPTIVGKS SLNPILFRGVGMVADPDNPLVLDILTGSSTSYSFFPDKPITQYPHAVG KNTLLIAGLQARNNARVIFSGSLDFFSDSFFNSAVQKAAPGSQRYSQ TGNYELAVALSRWVFKEEGVLRVGPVSHHRVGETAPPNAYTVTDL VEYSIVIQQLSNGKWVPFDGDDIQLEFVRIDPFVRTFLKKKGGKYSV QFKLPDVYGVFQFKVDYNRLGYTHLYSSTQVSVRPLQHTQYERFIP SAYPYYASAFSMMLGLFIFSIVFLHMKEKEKSD 245 MTGLYELVWRVLHALLCLHRTLTSWLRVRFGTWNWIWRRCCRAA NUS1 SAAVLAPLGFTLRKPPAVGRNRRHHRHPRGGSCLAAAHHRMRWR ADGRSLEKLPVHMGLVITEVEQEPSFSDIASLVVWCMAVGISYISVY DHQGIFKRNNSRLMDEILKQQQELLGLDCSKYSPEFANSNDKDDQV LNCHLAVKVLSPEDGKADIVRAAQDFCQLVAQKQKRPTDLDVDTL ASLLSSNGCPDPDLVLKFGPVDSTLGFLPWHIRLTEIVSLPSHLNISYE DFFSALRQYAACEQRLGK 246 MAPPGSSTVFLLALTIIASTWALTPTHYLTKHDVERLKASLDRPFTN RPN2 LESAFYSIVGLSSLGAQVPDAKKACTYIRSNLDPSNVDSLFYAAQAS QALSGCEISISNETKDLLLAAVSEDSSVTQIYHAVAALSGFGLPLASQ EALSALTARLSKEETVLATVQALQTASHLSQQADLRSIVEEIEDLVA RLDELGGVYLQFEEGLETTALFVAATYKLMDHVGTEPSIKEDQVIQ LMNAIFSKKNFESLSEAFSVASAAAVLSHNRYHVPVVVVPEGSASD THEQAILRLQVTNVLSQPLTQATVKLEHAKSVASRATVLQKTSFTP VGDVFELNFMNVKFSSGYYDFLVEVEGDNRYIANTVELRVKISTEV GITNVDLSTVDKDQSIAPKTTRVTYPAKAKGTFIADSHQNFALFFQL VDVNTGAELTPHQTFVRLHNQKTGQEVVFVAEPDNKNVYKFELDT SERKIEFDSASGTYTLYLIIGDATLKNPILWNVADVVIKFPEEEAPST VLSQNLFTPKQEIQHLFREPEKRPPTV VSNTFTALILSPLLLLFALWIRIGANVSNFTFAPSTIIFHLGHAAMLGL MYVYWTQLNMFQTLKYLAILGSVTFLAGNRMLAQQAVKRTAH 247 MTTYLEFIQQNEERDGVRFSWNVWPSSRLEATRMVVPVAALFTPLK SEC23A ERPDLPPIQYEPVLCSRTTCRAVLNPLCQVDYRAKLWACNFCYQRN QFPPSYAGISELNQPAELLPQFSSIEYVVLRGPQMPLIFLYVVDTCME DEDLQALKESMQMSLSLLPPTALVGLITFGRMVQVHELGCEGISKS YVFRGTKDLSAKQLQEMLGLSKVPLTQATRGPQVQQPPPSNRFLQP VQKIDMNLTDLLGELQRDPWPVPQGKRPLRSSGVALSIAVGLLECT FPNTGARIMMFIGGPATQGPGM VVGDELKTPIRSWHDIDKDNAKYVKKGTKHFEALANRAATTGHVI DIYACALDQTGLLEMKCCPNLTGGYMVMGDSFNTSLFKQTFQRVF TKDMHGQFKMGFGGTLEIKTSREIKISGAIGPCVSLNSKGPCVSENEI GTGGTCQWKICGLSPTTTLAIYFEVVNQHNAPIPQGGRGAIQFVTQY QHSSGQRRIRVTTIARNWADAQTQIQNIAASFDQEAAAILMARLAIY RAETEEGPDVLRWLDRQLIRLCQKFGEYHKDDPSSFRFSETFSLYPQ FMFHLRRSSFLQVFNNSPDESSYYRHHFMRQDLTQSLIMIQPILYAY SFSGPPEPVLLDSSSILADRILLMDTFFQILIYHGETIAQWRKSGYQD MPEYENFRHLLQAPVDDAQEILHSRFPMPRYIDTEHGGSQARFLLSK VNPSQTHNNMYAWGQESGAPILTDDVSLQVFMDHLKKLAVSSAA 248 MFANLKYVSLGILVFQTTSLVLTMRYSRTLKEEGPRYLSSTAVVVA SLC35A3 ELLKIMACILLVYKDSKCSLRALNRVLHDEILNKPMETLKLAIPSGIY TLQNNLLYVALSNLDAATYQVTYQLKILTTALFSVSMLSKKLGVYQ WLSLVILMTGVAFVQWPSDSQLDSKELSAGSQFVGLMAVLTACFSS GFAGVYFEKILKETKQSVWIRNIQLGFFGSIFGLMGVYIYDGELVSK NGFFQGYNRLTWIVVVLQALGGLVIAAVIKYADNILKGFATSLSIILS TLISYFWLQDFVPTSVFFLGAILVITATFLYGYDPKPAGNPTKA 249 MGLLVFVRNLLLALCLFLVLGFLYYSAWKLHLLQWEEDSNSVVLS ST3GAL3 FDSAGQTLGSEYDRLGFLLNLDSKLPAELATKYANFSEGACKPGYA SALMTAIFPRFSKPAPMFLDDSFRKWARIREFVPPFGIKGQDNLIKAI LSVTKEYRLTPALDSLRCRRCIIVGNGGVLANKSLGSRIDDYDIVVR LNSAPVKGFEKDVGSKTTLRITYPEGAMQRPEQYERDSLFVLAGFK WQDFKWLKYIVYKERVSASDGFWKSVATRVPKEPPEIRILNPYFIQE AAFTLIGLPFNNGLMGRGNIPTLGSVAVTMALHGCDEVAVAGFGY DMSTPNAPLHYYETVRMAAIKESWTHNIQREKEFLRKLVKARVITD LSSGI 250 MTKFGFLRLSYEKQDTLLKLLILSMAAVLSFSTRLFAVLRFESVIHEF STT3A DPYFNYRTTRFLAEEGFYKFHNWFDDRAWYPLGRIIGGTIYPGLMIT SAAIYHVLHFFHITIDIRNVCVFLAPLFSSFTTIVTYHLTKELKDAGA GLLAAAMIAVVPGYISRSVAGSYDNEGIAIFCMLLTYYMWIKAVKT GSICWAAKCALAYFYMVSSWGGYVFLINLIPLHVLVLMLTGRFSHR IYVAYCTVYCLGTILSMQISFVGFQPVLSSEHMAAFGVFGLCQIHAF VDYLRSKLNPQQFEVLFRSVISLVGFVLLTVGALLMLTGKISPWTGR FYSLLDPSYAKNNIPIIASVSEHQPTTWSSYYFDLQLLVFMFPVGLYY CFSNLSDARIFIIMYGVTSMYFSAVMVRLMLVLAPVMCILSGIGVSQ VLSTYMKNLDISRPDKKSKKQQDSTYPIKNEVASGMILVMAFFLITY TFHSTWVTSEAYSSPSIVLSARGGDGSRIIFDDFREAYYWLRHNTPE DAKVMSWWDYGYQITAMANRTILVDNNTWNNTHISRVGQAMAST EEKAYEIMRELDVSYVLVIFGGLTGYSSDDINKFLWMVRIGGSTDT GKHIKENDYYTPTGEFRVDREGSPVLLNCLMYKMCYYRFGQVYTE AKRPPGFDRVRNAEIGNKDFELDVLEEAYTTEHWLVRIYKVKDLDN RGLSRT 251 MAEPSAPESKHKSSLNSSPWSGLMALGNSRHGHHGPGAQCAHKAA STT3B GGAAPPKPAPAGLSGGLSQPAGWQSLLSFTILFLAWLAGFSSRLFAV IRFESIIHEFDPWFNYRSTHHLASHGFYEFLNWFDERAWYPLGRIVG GTVYPGLMITAGLIHWILNTLNITVHIRDVCVFLAPTFSGLTSISTFLL TRELWNQGAGLLAACFIAIVPGYISRSVAGSFDNEGIAIFALQFTYYL WVKSVKTGSVFWTMCCCLSYFYMVSAWGGYVFIINLIPLHVFVLLL MQRYSKRVYIAYSTFYIVGLILSMQIPFVGFQPIRTSEHMAAAGVFA LLQAYAFLQYLRDRLTKQEFQTLFFLGVSLAAGAVFLSVIYLTYTG YIAPWSGRFYSLWDTGYAKIHIPIIASVSEHQPTTWVSFFFDLHILVC TFPAGLWFCIKNINDERVFVALYAISAVYFAGVMVRLMLTLTPVVC MLSAIAFSNVFEHYLGDDMKRENPPVEDSSDEDDKRNQGNLYDKA GKVRKHATEQEKTEEGLGPNIKSIVTMLMLMLLMMFAVHCTWVTS NAYSSPSVVLASYNHDGTRNILDDFREAYFWLRQNTDEHARVMSW WDYGYQIAGMANRTTLVDNNTWNNSHIALVGKAMSSNETAAYKI MRTLDVDYVLVIFGGVIGYSGDDINKFLWMVRIAEGEHPKDIRESD YFTPQGEFRVDKAGSPTLLNCLMYKMSYYRFGEMQLDFRTPPGFD RTRNAEIGNKDIKFKHLEEAFTSEHWLVRIYKVKAPDNRETLDHKP RVTNIFPKQKYLSKKTTKRKRGYIKNKLVFKKGKKISKKTV 252 MARKSNLPVLLVPFLLCQALVRCSSPLPLVVNTWPFKNATEAAWR AGA ALASGGSALDAVESGCAMCEREQCDGSVGFGGSPDELGETTLDAMI MDGTTMDVGAVGDLRRIKNAIGVARKVLEHTTHTLLVGESATTFA QSMGFINEDLSTTASQALHSDWLARNCQPNYWRNVIPDPSKYCGPY KPPGILKQDIPIHKETEDDRGHDTIGMVVIHKTGHIAAGTSTNGIKFK IHGRVGDSPIPGAGAYADDTAGAAAATGNGDILMRFLPSYQAVEY MRRGEDPTIACQKVISRIQKHFPEF FGAVICANVTGSYGAACNKLSTFTQFSFMVYNSEKNQPTEEKVDCI 253 MGAPRSLLLALAAGLAVARPPNIVLIFADDLGYGDLGCYGHPSSTTP ARSA NLDQLAAGGLRFTDFYVPVSLCTPSRAALLTGRLPVRMGMYPGVL VPSSRGGLPLEEVTVAEVLAARGYLTGMAGKWHLGVGPEGAFLPP HQGFHRFLGIPYSHDQGPCQNLTCFPPATPCDGGCDQGLVPIPLLAN LSVEAQPPWLPGLEARYMAFAHDLMADAQRQDRPFFLYYASHHTH YPQFSGQSFAERSGRGPFGDSLMELDAAVGTLMTAIGDLGLLEETL VIFTADNGPETMRMSRGGCSGLLRC GKGTTYEGGVREPALAFWPGHIAPGVTHELASSLDLLPTLAALAGA PLPNVTLDGFDLSPLLLGTGKSPRQSLFFYPSYPDEVRGVFAVRTGK YKAHFFTQGSAHSDTTADPACHASSSLTAHEPPLLYDLSKDPGENY NLLGGVAGATPEVLQALKQLQLLKAQLDAAVTFGPSQVARGEDPA LQICCHPGCTPRPACCHCPDPHA 254 MGPRGAASLPRGPGPRRLLLPVVLPLLLLLLLAPPGSGAGASRPPHL ARSB VFLLADDLGWNDVGFHGSRIRTPHLDALAAGGVLLDNYYTQPLCT PSRSQLLTGRYQIRTGLQHQIIWPCQPSCVPLDEKLLPQLLKEAGYTT HMVGKWHLGMYRKECLPTRRGFDTYFGYLLGSEDYYSHERCTLID ALNVTRCALDFRDGEEVATGYKNMYSTNIFTKRAIALITNHPPEKPL FLYLALQSVHEPLQVPEEYLKPYDFIQDKNRHHYAGMVSLMDEAV GNVTAALKSSGLWNNTVFIFSTDNGGQTLAGGNNWPLRGRKWSL WEGGVRGVGFVASPLLKQKGVKNRELIHISDWLPTLVKLARGHTN GTKPLDGFDVWKTISEGSPSPRIELLHNIDPNFVDSSPCPRNSMAPAK DDSSLPEYSAFNTSVHAAIRHGNWKLLTGYPGCGYWFPPPSQYNVS EIPSSDPPTKTLWLFDIDRDPEERHDLSREYPHIVTKLLSRLQFYHKH SVPVYFPAQDPRCDPKATGVWGPWM 255 MPGRSCVALVLLAAAVSCAVAQHAPPWTEDCRKSTYPPSGPTYRG ASAH1 AVPWYTINLDLPPYKRWHELMLDKAPVLKVIVNSLKNMINTFVPSG KIMQVVDEKLPGLLGNFPGPFEEEMKGIAAVTDIPLGEIISFNIFYELF TICTSIVAEDKKGHLIHGRNMDFGVFLGWNINNDTWVITEQLKPLTV NLDFQRNNKTVFKASSFAGYVGMLTGFKPGLFSLTLNERFSINGGY LGILEWILGKKDVMWIGFLTRTVLENSTSYEEAKNLLTKTKILAPAY FILGGNQSGEGCVITRDRKESLDVYELDAKQGRWYVVQTNYDRWK HPFFLDDRRTPAKMCLNRTSQENISFETMYDVLSTKPVLNKLTVYT TLIDVTKGQFETYLRDCPDPCIGW 256 MSADSSPLVGSTPTGYGTLTIGTSIDPLSSSVSSVRLSGYCGSPWRVI ATP13A2 GYHVVVWMMAGIPLLLFRWKPLWGVRLRLRPCNLAHAETLVIEIR DKEDSSWQLFTVQVQTEAIGEGSLEPSPQSQAEDGRSQAAVGAVPE GAWKDTAQLHKSEEAVSVGQKRVLRYYLFQGQRYIWIETQQAFYQ VSLLDHGRSCDDVHRSRHGLSLQDQMVRKAIYGPNVISIPVKSYPQ LLVDEALNPYYGFQAFSIALWLADHYYWYALCIFLISSISICLSLYKT RKQSQTLRDMVKLSMRVCVCRPGGEEEWVDSSELVPGDCLVLPQE GGLMPCDAALVAGECMVNESSLTGESIPVLKTALPEGLGPYCAETH RRHTLFCGTLILQARAYVGPHVLAVVTRTGFCTAKGGLVSSILHPRP INFKFYKHSMKFVAALSVLALLGTIYSIFILYRNRVPLNEIVIRALDL VTVVVPPALPAAMTVCTLYAQSRLRRQGIFCIHPLRINLGGKLQLVC FDKTGTLTEDGLDVMGVVPLKGQAFLPLV PEPRRLPVGPLLRALATCHALSRLQDTPVGDPMDLKMVESTGWVL EEEPAADSAFGTQVLAVMRPPLWEPQLQAMEEPPVPVSVLHRFPFS SALQRMSVVVAWPGATQPEAYVKGSPELVAGLCNPETVPTDFAQM LQSYTAAGYRVVALASKPLPTVPSLEAAQQLTRDTVEGDLSLLGLL VMRNLLKPQTTPVIQALRRTRIRAVMVTGDNLQTAVTVARGCGMV APQEHLHVHATHPERGQPASLEFLPMESPTAVNGVKDPDQAASYTV EPDPRSRHLALSGPTFGIIVKHFPKL LPKVLVQGTVFARMAPEQKTELVCELQKLQYCVGMCGDGANDCG ALKAADVGISLSQAEASVVSPFTSSMASIECVPMVIREGRCSLDTSFS VFKYMALYSLTQFISVLILYTINTNLGDLQFLAIDLVITTTVAVLMSR TGPALVLGRVRPPGALLSVPVLSSLLLQMVLVTGVQLGGYFLTLAQ PWFVPLNRTVAAPDNLPNYENTVVFSLSSFQYLILAAAVSKGAPFRR PLYTNVPFLVALALLSSVLVGLVLVPGLLQGPLALRNITDTGFKLLL LGLVTLNFVGAFMLESVLDQCLPACLRRLRPKRASKKRFKQLEREL AEQPWPPLPAGPLR 257 MGGCAGSRRRFSDSEGEETVPEPRLPLLDHQGAHWKNAVGFWLLG CLN3 LCNNFSYVVMLSAAHDILSHKRTSGNQSHVDPGPTPIPHNSSSRFDC NSVSTAAVLLADILPTLVIKLLAPLGLHLLPYSPRVLVSGICAAGSFV LVAFSHSVGTSLCGVVFASISSGLGEVTFLSLTAFYPRAVISWWSSG TGGAGLLGALSYLGLTQAGLSPQQTLLSMLGIPALLLASYFLLLTSP EAQDPGGEEEAESAARQPLIRTEAPESKPGSSSSLSLRERWTVFKGL LWYIVPLVVVYFAEYFINQGLFELLFFWNTSLSHAQQYRWYQMLY QAGVFASRSSLRCCRIRFTWALALLQCLNLVFLLADVWFGFLPSIYL VFLIILYEGLLGGAAYVNTFHNIALETSDEHREFAMAATCISDTLGIS LSGLLALPLHDFLCQLS 258 MAQEVDTAQGAEMRRGAGAARGRASWCWALALLWLAVVPGWS CLN5 RVSGIPSRRHWPVPYKRFDFRPKPDPYCQAKYTFCPTGSPIPVMEGD DDIEVFRLQAPVWEFKYGDLLGHLKIMHDAIGFRSTLTGKNYTME WYELFQLGNCTFPHLRPEMDAPFWCNQGAACFFEGIDDVHWKENG TLVQVATISGNMFNQMAKWVKQDNETGIYYETWNVKASPEKGAE TWFDSYDCSKFVLRTFNKLAEFGAEFKNIETNYTRIFLYSGEPTYLG NETSVFGPTGNKTLGLAIKRFYYPFKPHLPTKEFLLSLLQIFDAVIVH KQFYLFYNFEYWFLPMKFPFIKITYEEIPLPIRNKTLSGL 259 MEATRRRQHLGATGGPGAQLGASFLQARHGSVSADEAARTAPFHL CLN6 DLWFYFTLQNWVLDFGRPIAMLVFPLEWFPLNKPSVGDYFHMAYN VITPFLLLKLIERSPRTLPRSITYVSIIIFIMGASIHLVGDSVNHRLLFSG YQHHLSVRENPIIKNLKPETLIDSFELLYYYDEYLGHCMWYIPFFLIL FMYFSGCFTASKAESLIPGPALLLVAPSGLYYWYLVTEGQIFILFIFTF FAMLALVLHQKRKRLFLDSNGLFLFSSFALTLLLVALWVAWLWND PVLRKKYPGVIYVPEPWAFYTLHVSSRH 260 MNPASDGGTSESIFDLDYASWGIRSTLMVAGFVFYLGVFVVCHQLS CLN8 SSLNATYRSLVAREKVFWDLAATRAVFGVQSTAAGLWALLGDPVL HADKARGQQNWCWFHITTATGFFCFENVAVHLSNLIFRTFDLFLVI HHLFAFLGFLGCLVNLQAGHYLAMTTLLLEMSTPFTCVSWMLLKA GWSESLFWKLNQWLMIHMFHCRMVLTYHMWWVCFWHWDGLVS SLYLPHLTLFLVGLALLTLIINPYWTHKKTQQLLNPVDWNFAQPEA KSRPEGNGQLLRKKRP 261 MIRNWLTIFILFPLKLVEKCESSVSLTVPPVVKLENGSSTNVSLTLRP CTNS PLNATLVITFEITFRSKNITILELPDEVVVPPGVTNSSFQVTSQNVGQL TVYLHGNHSNQTGPRIRFLVIRSSAISIINQVIGWIYFVAWSISFYPQV IMNWRRKSVIGLSFDFVALNLTGFVAYSVFNIGLLWVPYIKEQFLLK YPNGVNPVNSNDVFFSLHAVVLTLIIIVQCCLYERGGQRVSWPAIGF LVLAWLFAFVTMIVAAVGVTTWLQFLFCFSYIKLAVTLVKYFPQAY MNFYYKSTEGWSIGNVLLDFTGGSFSLLQMFLQSYNNDQWTLIFGD PTKFGLGVFSIVFDVVFFIQHFCLYRKRPGYDQLN 262 MIRAAPPPLFLLLLLLLLLVSWASRGEAAPDQDEIQRLPGLAKQPSF CTSA RQYSGYLKGSGSKHLHYWFVESQKDPENSPVVLWLNGGPGCSSLD GLLTEHGPFLVQPDGVTLEYNPYSWNLIANVLYLESPAGVGFSYSD DKFYATNDTEVAQSNFEALQDFFRLFPEYKNNKLFLTGESYAGIYIP TLAVLVMQDPSMNLQGLAVGNGLSSYEQNDNSLVYFAYYHGLLG NRLWSSLQTHCCSQNKCNFYDNKDLECVTNLQEVARIVGNSGLNIY NLYAPCAGGVPSHFRYEKDTVVVQD LGNIFTRLPLKRMWHQALLRSGDKVRMDPPCTNTTAASTYLNNPY VRKALNIPEQLPQWDMCNFLVNLQYRRLYRSMNSQYLKLLSSQKY QILLYNGDVDMACNFMGDEWFVDSLNQKMEVQRRPWLVKYGDS GEQIAGFVKEFSHIAFLTIKGAGHMVPTDKPLAAFTMFSRFLNKQPY 263 MQPSSLLPLALCLLAAPASALVRIPLHKFTSIRRTMSEVGGSVEDLIA CTSD KGPVSKYSQAVPAVTEGPIPEVLKNYMDAQYYGEIGIGTPPQCFTV VFDTGSSNLWVPSIHCKLLDIACWIHHKYNSDKSSTYVKNGTSFDIH YGSGSLSGYLSQDTVSVPCQSASSASALGGVKVERQVFG EATKQPGITFIAAKFDGILGMAYPRISVNNVLPVFDNLMQQKLVDQ NIFSFYLSRDPDAQPGGELMLGGTDSKYYKGSLSYLNVTRKAYWQ VHLDQVEVASGLTLCKEGCEAIVDTGTSLMVGPVDEVRELQKAIGA VPLIQGEYMIPCEKVSTLPAITLKLGGKGYKLSPEDYTLKVSQAGKT LCLSGFMGMDIPPPSGPLWILGDVFIGRYYTVFDRDNNRVGFAEAA RL 264 MAPWLQLLSLLGLLPGAVAAPAQPRAASFQAWGPPSPELLAPTRFA CTSF LEMFNRGRAAGTRAVLGLVRGRVRRAGQGSLYSLEATLEEPPCND PMVCRLPVSKKTLLCSFQVLDELGRHVLLRKDCGPVDTKVPGAGEP KSAFTQGSAMISSLSQNHPDNRNETFSSVISLLNEDPLSQDLPVKMA SIFKNFVITYNRTYESKEEARWRLSVFVNNMVRAQKIQALDRGTAQ YGVTKFSDLTEEEFRTIYLNTLLRKEPGNKMKQAKSVGDLAPPEWD WRSKGAVTKVKDQGMCGSCWAFSVTGNVEGQWFLNQGTLLSLSE QELLDCDKMDKACMGGLPSNAYSAIKNLGGLETEDDYSYQGHMQ SCNFSAEKAKVYINDSVELSQNEQKLAAWLAKRGPISVAINAFGMQ FYRHGISRPLRPLCSPWLIDHAVLLVGYGNRSDVPFWAIKNSWGTD WGEKGYYYLHRGSGACGVNTMASSAVVD 265 MWGLKVLLLPVVSFALYPEEILDTHWELWKKTHRKQYNNKVDEIS CTSK RRLIWEKNLKYISIHNLEASLGVHTYELAMNHLGDMTSEEVVQKMT GLKVPLSHSRSNDTLYIPEWEGRAPDSVDYRKKGYVTPVKNQGQC GSCWAFSSVGALEGQLKKKTGKLLNLSPQNLVDCVSENDGCGGGY MTNAFQYVQKNRGIDSEDAYPYVGQEESCMYNPTGKAAKCRGYR EIPEGNEKALKRAVARVGPVSVAIDASLTSFQFYSKGVYYDESCNSD NLNHAVLAVGYGIQKGNKHWIIKNSWGENWGNKGYILMARNKNN ACGIANLASFPKM 266 MADQRQRSLSTSGESLYHVLGLDKNATSDDIKKSYRKLALKYHPD DNAJC5 KNPDNPEAADKFKEINNAHAILTDATKRNIYDKYGSLGLYVAEQFG EENVNTYFVLSSWWAKALFVFCGLLTCCYCCCCLCCCFNCCCGKC KPKAPEGEETEFYVSPEDLEAQLQSDEREATDTPIVIQPASATETTQL TADSHPSYHTDGFN 267 MRAPGMRSRPAGPALLLLLLFLGAAESVRRAQPPRRYTPDWPSLDS FUCA1 RPLPAWFDEAKFGVFIHWGVFSVPAWGSEWFWWHWQGEGRPQYQ RFMRDNYPPGFSYADFGPQFTARFFHPEEWADLFQAAGAKYVVLT TKHHEGFTNWPSPVSWNWNSKDVGPHRDLVGELGTALRKRNIRYG LYHSLLEWFHPLYLLDKKNGFKTQHFVSAKTMPELYDLVNSYKPD LIWSDGEWECPDTYWNSTNFLSWLYNDSPVKDEVVVNDRWGQNC SCHHGGYYNCEDKFKPQSLPDHKWEMCTSIDKFSWGYRRDMALSD VTEESEIISELVQTVSLGGNYLLNIGPTKDGLIVPIFQERLLAVGK WLSINGEAIYASKPWRVQWEKNTTSVWYTSKGSAVYAIFLHWPEN GVLNLESPITTSTTKITMLGIQGDLKWSTDPDKGLFISLPQLPPSAVP AEFAWTIKLTGVK 268 MGVRHPPCSHRLLAVCALVSLATAALLGHILLHDFLLVPRELSGSSP GAA VLEETHPAHQQGASRPGPRDAQAHPGRPRAVPTQCDVPPNSRFDCA PDKAITQEQCEARGCCYIPAKQGLQGAQMGQPWCFFPPSYPSYKLE NLSSSEMGYTATLTRTTPTFFPKDILTLRLDVMMETENRLHFTIKDP ANRRYEVPLETPHVHSRAPSPLYSVEFSEEPFGVIVRRQLDGRVLLN TTVAPLFFADQFLQLSTSLPSQYITGLAEHLSPLMLSTSWTRITLWNR DLAPTPGANLYGSHPFYLALEDGGSAHGVFLLNSNAMDVVLQPSPA LSWRSTGGILDVYIFLGPEPKSVVQQYLDVVGYPFMPPYWGLGFHL CRWGYSSTAITRQVVENMTRAHFPLDVQWNDLDYMDSRRDFTFN KDGFRDFPAMVQELHQGGRRYMMIVDPAISSSGPAGSYRPYDEGLR RGVFITNETGQPLIGKVWPGSTAFPDFTNPTALAWWEDMVAEFHD QVPFDGMWIDMNEPSNFIRGSEDGCPNNELENPPYVPGVVGGTLQA ATICASSHQFLSTHYNLHNLYGLTEAIASHRALVKARGTRPFVISRST FAGHGRYAGHWTGDVWSSWEQLASSVPEILQFNLLGVPLVGADVC GFLGNTSEELCVRWTQLGAFYPFMRNHNSLLSLPQEPYSFSEPAQQ AMRKALTLRYALLPHLYTLFHQAHVAGETVARPLFLEFPKDSSTWT VDHQLLWGEALLITPVLQAGKAEVTGYFPLGTWYDLQTVPVEALG SLPPPPAAPREPAIHSEGQWVTLPAPLDTINVHLRAGYIIPLQGPGLT TTESRQQPMALAVALTKGGEARGELFWDDGESLEVLERGAYTQVIF LARNNTIVNELVRVTSEGAGLQLQKVTVLGVATAPQQVLSNGVPVS NFTYSPDTKVLDICVSLLMGEQFLVSWC 269 MAEWLLSASWQRRAKAMTAAAGSAGRAAVPLLLCALLAPGGAYV GALC LDDSDGLGREFDGIGAVSGGGATSRLLVNYPEPYRSQILDYLFKPNF GASLHILKVEIGGDGQTTDGTEPSHMHYALDENYFRGYEWWLMKE AKKRNPNITLIGLPWSFPGWLGKGFDWPYVNLQLTAYYVVTWIVG AKRYHDLDIDYIGIWNERSYNANYIKILRKMLNYQGLQRVKIIASDN LWESISASMLLDAELFKVVDVIGAHYPGTHSAKDAKLTGKKLWSSE DFSTLNSDMGAGCWGRILNQNYINGYMTSTIAWNLVASYYEQLPY GRCGLMTAQEPWSGHYVVESPVWVSAHTTQFTQPGWYYLKTVGH LEKGGSYVALTDGLGNLTIIIETMSHKHSKCIRPFLPYFNVSQQFATF VLKGSFSEIPELQVWYTKLGKTSERFLFKQLDSLWLLDSDGSFTLSL HEDELFTLTTLTTGRKGSYPLPPKSQPFPSTYKDDFNVDYPFFSEAPN FADQTGVFEYFTNIEDPGEHHFTLRQVLNQRPITWAADASNTISIIGD YNWTNLTIKCDVYIETPDTGGVFIAGRVNKGGILIRSARGIFFWIFAN GSYRVTGDLAGWIIYALGRVEVTAKKWYTLTLTIKGHFTSGMLND KSLWTDIPVNFPKNGWAAIGTHSFEFAQFDNFLVEATR 270 MAAVVAATRWWQLLLVLSAAGMGASGAPQPPNILLLLMDDMGW GALNS GDLGVYGEPSRETPNLDRMAAEGLLFPNFYSANPLCSPSRAALLTG RLPIRNGFYTTNAHARNAYTPQEIVGGIPDSEQLLPELLKKAGYVSKI VGKWHLGHRPQFHPLKHGFDEWFGSPNCHFGPYDNKARPNIPVYR DWEMVGRYYEEFPINLKTGEANLTQIYLQEALDFIKRQARHHPFFL YWAVDATHAPVYASKPFLGTSQRGRYGDAVREIDDSIGKILELLQD LHVADNTFVFFTSDNGAALISAPEQGGSNGPFLCGKQTTFEGGMRE PALAWWPGHVTAGQVSHQLGSIMDLFTTSLALAGLTPPSDRAIDGL NLLPTLLQGRLMDRPIFYYRGDTLMAATLGQHKAHFWTWTNSWE NFRQGIDFCPGQNVSGVTTHNLEDHTKLPLIFHLGRDPGERFPLSFAS AEYQEALSRITSVVQQHQEALVPAQPQLNVCNWAVMNWAPPGCE KLGKCLTPPESIPKKCLWSH 271 MQLRNPELHLGCALALRFLALVSWDIPGARALDNGLARTPTMGWL GLA HWERFMCNLDCQEEPDSCISEKLFMEMAELMVSEGWKDAGYEYL CIDDCWMAPQRDSEGRLQADPQRFPHGIRQLANYVHSKGLKLGIYA DVGNKTCAGFPGSFGYYDIDAQTFADWGVDLLKFDGCYCDSLENL ADGYKHMSLALNRTGRSIVYSCEWPLYMWPFQKPNYTEIRQYCNH WRNFADIDDSWKSIKSILDWTSFNQERIVDVAGPGGWNDPDMLVIG NFGLSWNQQVTQMALWAIMAAPLFMSNDLRHISPQAKALLQDKD VIAINQDPLGKQGYQLRQGDNFEVWERPLSGLAWAVAMINRQEIG GPRSYTIAVASLGKGVACNPACFITQLLPVKRKLGFYEWTSRLRSHI NPTGTVLLQLENTMQMSLKDLL 272 MPGFLVRILPLLLVLLLLGPTRGLRNATQRMFEIDYSRDSFLKDGQP GLB1 FRYISGSIHYSRVPRFYWKDRLLKMKMAGLNAIQTYVPWNFHEPW PGQYQFSEDHDVEYFLRLAHELGLLVILRPGPYICAEWEMGGLPAW LLEKESILLRSSDPDYLAAVDKWLGVLLPKMKPLLYQNGGPVITVQ VENEYGSYFACDFDYLRFLQKRFRHHLGDDVVLFTTDGAHKTFLK CGALQGLYTTVDFGTGSNITDAFLSQRKCEPKGPLINSEFYTGWLDH WGQPHSTIKTEAVASSLYDILARG ASVNLYMFIGGTNFAYWNGANSPYAAQPTSYDYDAPLSEAGDLTE KYFALRNIIQKFEKVPEGPIPPSTPKFAYGKVTLEKLKTVGAALDILC PSGPIKSLYPLTFIQVKQHYGFVLYRTTLPQDCSNPAPLSSPLNGVHD RAYVAVDGIPQGVLERNNVITLNITGKAGATLDLLVENMGRVNYG AYINDFKGLVSNLTLSSNILTDWTIFPLDTEDAVRSHLGGWGHRDSG HHDEAWAHNSSNYTLPAFYMGNFSIPSGIPDLPQDTFIQFPGWTKGQ VWINGFNLGRYWPARGPQLTLFVPQHILMTSAPNTITVLELEWAPC SSDDPELCAVTFVDRPVIGSSVTYDHPSKPVEKRLMPPPPQKNKDS WLDHV 273 MQSLMQAPLLIALGLLLAAPAQAHLKKPSQLSSFSWDNCDEGKDPA GM2A VIRSLTLEPDPIIVPGNVTLSVMGSTSVPLSSPLKVDLVLEKEVAGLW IKIPCTDYIGSCTFEHFCDVLDMLIPTGEPCPEPLRTYGLPCHCPFKEG TYSLPKSEFVVPDLELPSWLTTGNYRIESVLSSSGKRLGCIKIAASLK GI 274 MLFKLLQRQTYTCLSHRYGLYVCFLGVVVTIVSAFQFGEVVLEWSR GNPTAB DQYHVLFDSYRDNIAGKSFQNRLCLPMPIDVVYTWVNGTDLELLKE LQQVREQMEEEQKAMREILGKNTTEPTKKSEKQLECLLTHCIKVPM LVLDPALPANITLKDLPSLYPSFHSASDIFNVAKPKNPSTNVSVVVFD STKDVEDAHSGLLKGNSRQTVWRGYLTTDKEVPGLVLMQDLAFLS GFPPTFKETNQLKTKLPENLSSKVKLLQLYSEASVALLKLNNPKDFQ ELNKQTKKNMTIDGKELTISPA YLLWDLSAISQSKQDEDISASRFEDNEELRYSLRSIERHAPWVRNIFI VTNGQIPSWLNLDNPRVTIVTHQDVFRNLSHLPTFSSPAIESHIHRIEG LSQKFIYLNDDVMFGKDVWPDDFYSHSKGQKVYLTWPVPNCAEGC PGSWIKDGYCDKACNNSACDWDGGDCSGNSGGSRYIAGGGGTGSI GVGQPWQFGGGINSVSYCNQGCANSWLADKFCDQACNVLSCGFD AGDCGQDHFHELYKVILLPNQTHYIIPKGECLPYFSFAEVAKRGVEG AYSDNPIIRHASIANKWKTIHLIMHSGMNATTIHFNLTFQNTNDEEF KMQITVEVDTREGPKLNSTAQKGYENLVSPITLLPEAEILFEDIPKEK RFPKFKRHDVNSTRRAQEEVKIPLVNISLLPKDAQLSLNTLDLQLEH GDITLKGYNLSKSALLRSFLMNSQHAKIKNQAIITDETNDSLVAPQE KQVHKSILPNSLGVSERLQRLTFPAVSVKVNGHDQGQNPPLDLETT ARFRVETHTQKTIGGNVTKEKPPSLIVPLESQMTKEKKITGKEKENS RMEENAENHIGVTEVLLGRKLQHYTDSYLGFLPWEKKKYFQDLLD EEESLKTQLAYFTDSKNTGRQLKDTFADSLRYVNKILNSKFGFTSRK VPAHMPHMIDRIVMQELQDMFPEEFDKTSFHKVRHSEDMQFAFSYF YYLMSAVQPLNISQVFDEVDTDQSGVLSDREIRTLATRIHELPLSLQ DLTGLEHMLINCSKMLPADITQLNNIPPTQESYYDPNLPPVTKSLVT NCKPVTDKIHKAYKDKNKYRFEIMGEEEIAFKMIRTNVSHVVGQLD DIRKNPRKFVCLNDNIDHNHKDAQTVKAVLRDFYESMFPIPSQFELP REYRNRFLHMHELQEWRAYRDKLKFWTHCVLATLIMFTIFSFFAEQ LIALKRKIFPRRRIHKEASPNRIRV 275 MAAGLARLLLLLGLSAGGPAPAGAAKMKVVEEPNAFGVNNPFLPQ GNPTG ASRLQAKRDPSPVSGPVHLFRLSGKCFSLVESTYKYEFCPFHNVTQH EQTFRWNAYSGILGIWHEWEIANNTFTGMWMRDGDACRSRSRQSK VELACGKSNRLAHVSEPSTCVYALTFETPLVCHPHALLVYPTLPEAL QRQWDQVEQDLADELITPQGHEKLLRTLFEDAGYLKTPEENEPTQL EGGPDSLGFETLENCRKAHKELSKEIKRLKGLLTQHGIPYTRPTETS NLEHLGHETPRAKSPEQLRGDPG LRGSL 276 MRLLPLAPGRLRRGSPRHLPSCSPALLLLVLGGCLGVFGVAAGTRR GNS PNVVLLLTDDQDEVLGGMTPLKKTKALIGEMGMTFSSAYVPSALC CPSRASILTGKYPHNHHVVNNTLEGNCSSKSWQKIQEPNTFPAILRS MCGYQTFFAGKYLNEYGAPDAGGLEHVPLGWSYWYALEKNSKYY NYTLSINGKARKHGENYSVDYLTDVLANVSLDFLDYKSNFEPFFM MIATPAPHSPWTAAPQYQKAFQNVFAPRNKNFNIHGTNKHWLIRQ AKTPMTNSSIQFLDNAFRKRWQTLLSVD DLVEKLVKRLEFTGELNNTYIFYTSDNGYHTGQFSLPIDKRQLYEFD IKVPLLVRGPGIKPNQTSKMLVANIDLGPTILDIAGYDLNKTQMDG MSLLPILRGASNLTWRSDVLVEYQGEGRNVTDPTCPSLSPGVSQCFP DCVCEDAYNNTYACVRTMSALWNLQYCEFDDQEVFVEVYNLTAD PDQITNIAKTIDPELLGKMNYRLMMLQSCSGPTCRTPGVFDPGYRFD PRLMFSNRGSVRTRRFSKHLL 277 MWTLVSWVALTAGLVAGTRCPDGQFCPVACCLDPGGASYSCCRPL GRN LDKWPTTLSRHLGGPCQVDAHCSAGHSCIFTVSGTSSCCPFPEAVAC GDGHHCCPRGFHCSADGRSCFQRSGNNSVGAIQCPDSQFECPDFST CCVMVDGSWGCCPMPQASCCEDRVHCCPHGAFCDLVHTRCITPTG THPLAKKLPAQRTNRAVALSSSVMCPDARSRCPDGSTCCELPSGKY GCCPMPNATCCSDHLHCCPQDTVCDLIQSKCLSKENATTDLLTKLP AHTVGDVKCDMEVSCPDGYTCCRLQSGAWGCCPFTQAVCCEDHIH CCPAGFTCDTQKGTCEQGPHQVPWMEKAPAHLSLPDPQALKRDVP CDNVSSCPSSDTCCQLTSGEWGCCPIPEAVCCSDHQHCCPQGYTCV AEGQCQRGSEIVAGLEKMPARRASLSHPRDIGCDQHTSCPVGQTCC PSLGGSWACCQLPHAVCCEDRQHCCPAGYTCNVKARSCEKEVVSA QPATFLARSPHVGVKDVECGEGHFCHDNQTCCRDNRQGWACCPY RQGVCCADRRHCCPAGFRCAARGTKCLRREAPRWDAPLRDPALRQ LL 278 MARGSAVAWAALGPLLWGCALGLQGGMLYPQESPSRECKELDGL GUSB WSFRADFSDNRRRGFEEQWYRRPLWESGPTVDMPVPSSFNDISQD WRLRHFVGWVWYEREVILPERWTQDLRTRVVLRIGSAHSYAIVWV NGVDTLEHEGGYLPFEADISNLVQVGPLPSRLRITIAINNTLTPTTLPP GTIQYLTDTSKYPKGYFVQNTYFDFFNYAGLQRSVLLYTTPTTYIDD ITVTTSVEQDSGLVNYQISVKGSNLFKLEVRLLDAENKVVANGTGT QGQLKVPGVSLWWPYLMHERPAYL YSLEVQLTAQTSLGPVSDFYTLPVGIRTVAVTKSQFLINGKPFYFHG VNKHEDADIRGKGFDWPLLVKDFNLLRWLGANAFRTSHYPYAEEV MQMCDRYGIVVIDECPGVGLALPQFFNNVSLHHHMQVMEEVVRR DKNHPAVVMWSVANEPASHLESAGYYLKMVIAHTKSLDPSRPVTF VSNSNYAADKGAPYVDVICLNSYYSWYHDYGHLELIQLQLATQFE NWYKKYQKPIIQSEYGAETIAGFHQDPPLMFTEEYQKSLLEQYHLG LDQKRRKYVVGELIWNFADFMTEQSPTRVLGNKKGIFTRQRQPKSA AFLLRERYWKIANETRYPHSVAKSQCLENSLFT 279 MTSSRLWFSLLLAAAFAGRATALWPWPQNFQTSDQRYVLYPNNFQ HEXA FQYDVSSAAQPGCSVLDEAFQRYRDLLFGSGSWPRPYLTGKRHTLE KNVLVVSVVTPGCNQLPTLESVENYTLTINDDQCLLLSETVWGALR GLETFSQLVWKSAEGTFFINKTEIEDFPRFPHRGLLLDTSRHYLPLSSI LDTLDVMAYNKLNVFHWHLVDDPSFPYESFTFPELMRKGSYNPVT HIYTAQDVKEVIEYARLRGIRVLAEFDTPGHTLSWGPGIPGLLTPCY SGSEPSGTFGPVNPSLNNTYEFMSTFFLEVSSVFPDFYLHLGGDEVD FTCWKSNPEIQDFMRKKGFGEDFKQLESFYIQTLLDIVSSYGKGYVV WQEVFDNKVKIQPDTIIQVWREDIPVNYMKELELVTKAGFRALLSA PWYLNRISYGPDWKDFYIVEPLAFEGTPEQKALVIGGEACMWGEY VDNTNLVPRLWPRAGAVAERLWSNKLTSDLTFAYERLSHFRCELLR RGVQAQPLNVGFCEQEFEQT 280 MELCGLGLPRPPMLLALLLATLLAAMLALLTQVALVVQVAEAARA HEXB PSVSAKPGPALWPLPLSVKMTPNLLHLAPENFYISHSPNSTAGPSCTL LEEAFRRYHGYIFGFYKWHHEPAEFQAKTQVQQLLVSITLQSECDA FPNISSDESYTLLVKEPVAVLKANRVWGALRGLETFSQLVYQDSYG TFTINESTIIDSPRFSHRGILIDTSRHYLPVKIILKTLDAMAFNKFNVLH WHIVDDQSFPYQSITFPELSNKGSYSLSHVYTPNDVRMVIEYARLRG IRVLPEFDTPGHTLSWGKGQKDLLTPCYSRQNKLDSFGPINPTLNTT YSFLTTFFKEISEVFPDQFIHLGGDEVEFKCWESNPKIQDFMRQKGF GTDFKKLESFYIQKVLDIIATINKGSIVWQEVFDDKAKLAPGTIVEV WKDSAYPEELSRVTASGFPVILSAPWYLDLISYGQDWRKYYKVEPL DFGGTQKQKQLFIGGEACLWGEYVDATNLTPRLWPRASAVGERLW SSKDVRDMDDAYDRLTRHRCRMVERG IAAQPLYAGYCNHENM 281 MTGARASAAEQRRAGRSGQARAAERAAGMSGAGRALAALLLAAS HGSNAT VLSAALLAPGGSSGRDAQAAPPRDLDKKRHAELKMDQALLLIHNE LLWTNLTVYWKSECCYHCLFQVLVNVPQSPKAGKPSAAAASVSTQ HGSILQLNDTLEEKEVCRLEYRFGEFGNYSLLVKNIHNGVSEIACDL AVNEDPVDSNLPVSIAFLIGLAVIIVISFLRLLLSLDDFNNWISKAISSR ETDRLINSELGSPSRTDPLDGDVQPATWRLSALPPRLRSVDTFRGIAL ILMVFVNYGGGKYWYFKHASWNGLTVADLVFPWFVFIMGSSIFLS MTSILQRGCSKFRLLGKIAWRSFLLICIGIIIVNPNYCLGPLSWDKVRI PGVLQRLGVTYFVVAVLELLFAKPVPEHCASERSCLSLRDITSSWPQ WLLILVLEGLWLGLTFLLPVPGCPTGYLGPGGIGDFGKYPNCTGGA AGYIDRLLLGDDHLYQHPSSAVLYHTEVAYDPEGILGTINSIVMAFL GVQAGKILLYYKARTKDILIRFTAWCC ILGLISVALTKVSENEGFIPVNKNLWSLSYVTTLSSFAFFILLVLYPVV DVKGLWTGTPFFYPGMNSILVYVGHEVFENYFPFQWKLKDNQSHK EHLTQNIVATALWVLIAYILYRKKIFWKI 282 MAAHLLPICALFLTLLDMAQGFRGPLLPNRPFTTVWNANTQWCLE HYAL1 RHGVDVDVSVFDVVANPGQTFRGPDMTIFYSSQLGTYPYYTPTGEP VFGGLPQNASLIAHLARTFQDILAAIPAPDFSGLAVIDWEAWRPRW AFNWDTKDIYRQRSRALVQAQHPDWPAPQVEAVAQDQFQGAARA WMAGTLQLGRALRPRGLWGFYGFPDCYNYDFLSPNYTGQCPSGIR AQNDQLGWLWGQSRALYPSIYMPAVLEGTGKSQMYVQHRVAEAF RVAVAAGDPNLPVLPYVQIFYDTTNHFLPLDELEHSLGESAAQGAA GVVLWVSWENTRTKESCQAIKEYMDTTLGPFILNVTSGALLCSQ ALCSGHGRCVRRTSHPKALLLLNPASFSIQLTPGGGPLSLRGALSLE DQAQMAVEFKCRCYPGWQAPWCERKSMW 283 MPPPRTGRGLLWLGLVLSSVCVALGSETQANSTTDALNVLLIIVDDL IDS RPSLGCYGDKLVRSPNIDQLASHSLLFQNAFAQQAVCAPSRVSFLTG RRPDTTRLYDFNSYWRVHAGNFSTIPQYFKENGYVTMSVGKVFHP GISSNHTDDSPYSWSFPPYHPSSEKYENTKTCRGPDGELHANLLCPV DVLDVPEGTLPDKQSTEQAIQLLEKMKTSASPFFLAVGYHKPHIPFR YPKEFQKLYPLENITLAPDPEVPDGLPPVAYNPWMDIRQREDVQAL NISVPYGPIPVDFQRKIRQSYFASVSYLDTQVGRLLSALDDLQLANS THAFTSDHGWALGEHGEWAKYSNFDVATHVPLIFYVPGRTASLPEA GEKLFPYLDPFDSASQLMEPGRQSMDLVELVSLFPTLAGLAGLQVP PRCPVPSFHVELCREGKNLLKHFRFRDLEEDPYLPGNPRELIAYSQY PRPSDIPQWNSDKPSLKDIKIMGYSIRTIDYRYTVWVGFNPDEFLAN FSDIHAGELYFVDSDPLQDHNMYNDSQGGDLFQLLMP 284 MRPLRPRAALLALLASLLAAPPVAPAEAPHLVHVDAARALWPLRRF IDUA WRSTGFCPPLPHSQADQYVLSWDQQLNLAYVGAVPHRGIKQVRTH WLLELVTTRGSTGRGLSYNFTHLDGYLDLLRENQLLPGFELMGSAS GHFTDFEDKQQVFEWKDLVSSLARRYIGRYGLAHVSKWNFETWNE PDHHDFDNVSMTMQGFLNYYDACSEGLRAASPALRLGGPGDSFHT PPRSPLSWGLLRHCHDGTNFFTGEAGVRLDYISLHRKGARSSISILEQ EKVVAQQIRQLFPKFADTPIYNDEADPLVGWSLPQPWRADVTYAA MVVKVIAQHQNLLLANTTSAFPYALLSNDNAFLSYHPHPFAQRTLT ARFQVNNTRPPHVQLLRKPVLTAMGLLALLDEEQLWAEVSQAGTV LDSNHTVGVLASAHRPQGPADAWRAAVLIYASDDTRAHPNRSVAV TLRLRGVPPGPGLVYVTRYLDNGLCSPDGEWRRLGRPVFPTAEQFR RMRAAEDPVAAAPRPLPAGGRLTLRPALRLPSLLLVHVCARPEKPP GQVTRLRALPLTQGQLVLVWSDEHVGSKCLWTYEIQFSQDGKAYT PVSRKPSTFNLFVFSPDTGAVSGSYRVRALDYWARPGPFSDPVPYLE VPVPRGPPSPGNP 285 MVVVTGREPDSRRQDGAMSSSDAEDDFLEPATPTATQAGHALPLLP KCTD7 QEFPEVVPLNIGGAHFTTRLSTLRCYEDTMLAAMFSGRHYIPTDSEG RYFIDRDGTHFGDVLNFLRSGDLPPRERVRAVYKEAQYYAIGPLLE QLENMQPLKGEKVRQAFLGLMPYYKDHLERIVEIARLRAVQRKAR FAKLKVCVFKEEMPITPYECPLLNSLRFERSESDGQLFEHHCEVDVS FGPWEAVADVYDLLHCLVTDLSAQGLTVDHQCIGVCDKHLVNHY YCKRPIYEFKITWW 286 MVCFRLFPVPGSGLVLVCLVLGAVRSYALELNLTDSENATCLYAK LAMP2 WQMNFTVRYETTNKTYKTVTISDHGTVTYNGSICGDDQNGPKIAV QFGPGFSWIANFTKAASTYSIDSVSFSYNTGDNTTFPDAEDKGILTV DELLAIRIPLNDLFRCNSLSTLEKNDVVQHYWDVLVQAFVQNGTVS TNEFLCDKDKTSTVAPTIHTTVPSPTTTPTPKEKPEAGTYSVNNGND TCLLATMGLQLNITQDKVASVININPNTTHSTGSCRSHTALLRLNSS TIIKYLDFVFAVKNENRFYLKEVNISMYLVNGSVFSIANNNLSYWDA PLGSSYMCNKEQTVSVSGAFQINTFDLRVQPFNVTQGKYSTAQDCS ADDDNFLVPIAVGAALAGVLILVLLAYFIGLKHHHAGYEQF 287 MGAYARASGVCARGCLDSAGPWTMSRALRPPLPPLCFFLLLLAAA MAN2B1 GARAGGYETCPTVQPNMLNVHLLPHTHDDVGWLKTVDQYFYGIK NDIQHAGVQYILDSVISALLADPTRRFIYVEIAFFSRWWHQQTNATQ EVVRDLVRQGRLEFANGGWVMNDEAATHYGAIVDQMTLGLRFLE DTFGNDGRPRVAWHIDPFGHSREQASLFAQMGFDGFFFGRLDYQD KWVRMQKLEMEQVWRASTSLKPPTADLFTGVLPNGYNPPRNLCW DVLCVDQPLVEDPRSPEYNAKELVDYFLNVATAQGRYYRTNHTVM TMGSDFQYENANMWFKNLDKLIRLVNAQQAKGSSVHVLYSTPAC YLWELNKANLTWSVKHDDFFPYADGPHQFWTGYFSSRPALKRYER LSYNFLQVCNQLEALVGLAANVGPYGSGDSAPLNEAMAVLQHHD AVSGTSRQHVANDYARQLAAGWGPCEVLLSNALARLRGFKDHFTF CQQLNISICPLSQTAARFQVIVYNPLGRKVNWMVRLPVSEGVFVVK DPNGRTVPSDVVIFPSSDSQAHPPELLFSASLPALGFSTYSVAQVPR WKPQARAPQPIPRRSWSPALTIENEHIRATFDPDTGLLMEIMNMNQ QLLLPVRQTFFWYNASIGDNESDQASGAYIFRPNQQKPLPVSRWAQI HLVKTPLVQEVHQNFSAWCSQVVRLYPGQRHLELEWSVGPIPVGD TWGKEVISRFDTPLETKGRFYTDSNGREILERRRDYRPTWKLNQTEP VAGNYYPVNTRIYITDGNMQLTVLTDRSQGGSSLRDGSLELMVHRR LLKDDGRGVSEPLMENGSGAWVRGRHLVLLDTAQAAAAGHRLLA EQEVLAPQVVLAPGGGAAYNLGAPPRTQFSGLRRDLPPSVHLLTLA SWGPEMVLLRLEHQFAVGEDSGRNLSAPVTLNLRDLFSTFTITRLQE TTLVANQLREAASRLKWTTNTGPTPHQTPYQLDPANITLEPMEIRTF LASVQWKEVDG 288 MRLHLLLLLALCGAGTTAAELSYSLRGNWSICNGNGSLELPGAVPG MANBA CVHSALFQQGLIQDSYYRFNDLNYRWVSLDNWTYSKEFKIPFEISK WQKVNLILEGVDTVSKILFNEVTIGETDNMFNRYSFDITNVVRDVNS IELRFQSAVLYAAQQSKAHTRYQVPPDCPPLVQKGECHVNFVRKEQ CSFSWDWGPSFPTQGIWKDVRIEAYNICHLNYFTFSPIYDKSAQEWN LEIESTFDVVSSKPVGGQVIVAIPKLQTQQTYSIELQPGKRIVELFVNI SKNITVETWWPHGHGNQTGYNMTVLFELDGGLNIEKSAKVYFRTV ELIEEPIKGSPGLSFYFKINGFPIFLKGSNWIPADSFQDRVTSELLRLLL QSVVDANMNTLRVWGGGIYEQDEFYELCDELGIMVWQDFMFACA LYPTDQGFLDSVTAEVAYQIKRLKSHPSIIIWSGNNENEEALMMNW YHISFTDRPIYIKDYVTLYVKNIRELVLAGDKSRPFITSSPTNGAETV AEAWVSQNPNSNYFGDVHFYDYISDC WNWKVFPKARFASEYGYQSWPSFSTLEKVSSTEDWSFNSKFSLHRQ HHEGGNKQMLYQAGLHFKLPQSTDPLRTFKDTIYLTQVMQAQCVK TETEFYRRSRSEIVDQQGHTMGALYWQLNDIWQAPSWASLEYGGK WKMLHYFAQNFFAPLLPVGFENENTFYIYGVSDLHSDYSMTLSVRV HTWSSLEPVCSRVTERFVMKGGEAVCLYEEPVSELLRRCGNCTRES CVVSFYLSADHELLSPTNYHFLSSPKEAVGLCKAQITAIISQQGDIFV FDLETSAVAPFVWLDVGSIPGRFSDNGFLMTEKTRTILFYPWEPTSK NELEQSFHVTSLTDIY 289 MTAPAGPRGSETERLLTPNPGYGTQAGPSPAPPTPPEEEDLRRRLKY MCOLN1 FFMSPCDKFRAKGRKPCKLMLQVVKILVVTVQLILFGLSNQLAVTF REENTIAFRHLFLLGYSDGADDTFAAYTREQLYQAIFHAVDQYLAL PDVSLGRYAYVRGGGDPWTNGSGLALCQRYYHRGHVDPANDTFDI DPMVVTDCIQVDPPERPPPPPSDDLTLLESSSSYKNLTLKFHKLVNV TIHFRLKTINLQSLINNEIPDCYTFSVLITFDNKAHSGRIPISLETQAHI QECKHPSVFQHGDNSFRLLFDVVVILTCSLSFLLCARSLLRGFLLQN EFVGFMWRQRGRVISLWERLEFVNGWYILLVTSDVLTISGTIMKIGI EAKNLASYDVCSILLGTSTLLVWVGVIRYLTFFHNYNILIATLRVALP SVMRFCCCVAVIYLGYCFCGWIVLGPYHVKFRSLSMVSECLFSLING DDMFVTFAAMQAQQGRSSLVWLFSQLYLYSFISLFIYMVLSLFIALI TGAYDTIKHPGGAGAEESELQAYIAQCQDSPTSGKFRRGSGSACSLL CCCGRDPSEEHSLLVN 290 MAGLRNESEQEPLLGDTPGSREWDILETEEHYKSRWRSIRILYLTMF MFSD8 LSSVGFSVVMMSIWPYLQKIDPTADTSFLGWVIASYSLGQMVASPIF GLWSNYRPRKEPLIVSILISVAANCLYAYLHIPASHNKYYMLVARGL LGIGAGNVAVVRSYTAGATSLQERTSSMANISMCQALGFILGPVFQ TCFTFLGEKGVTWDVIKLQINMYTTPVLLSAFLGILNIILILAILREHR VDDS GRQCKSINFEEASTDEAQVPQGNIDQVAVVAINVLFFVTLFIFALFET IITPLTMDMYAWTQEQAVLYNGIILAALGVEAVVIFLGVKLLSKKIG ERAILLGGLIVVWVGFFILLPWGNQFPKIQWEDLHNNSIPNTTFGEIII GLWKSPMEDDNERPTGCSIEQAWCLYTPVIHLAQFLTSAVLIGLGYP VCNLMSYTLYSKILGPKPQGVYMGWLTASGSGARILGPMFISQVYA HWGPRWAFSLVCGIIVLTITLLGVVYKRLIALSVRYGRIQE 291 MLLKTVLLLGHVAQVLMLDNGLLQTPPMGWLAWERFRCNINCDE NAGA DPKNCISEQLFMEMADRMAQDGWRDMGYTYLNIDDCWIGGRDAS GRLMPDPKRFPHGIPFLADYVHSLGLKLGIYADMGNFTCMGYPGTT LDKVVQDAQTFAEWKVDMLKLDGCFSTPEERAQGYPKMAAALNA TGRPIAFSCSWPAYEGGLPPRVNYSLLADICNLWRNYDDIQDSWWS VLSILNWFVEHQDILQPVAGPGHWNDPDMLLIGNFGLSLEQSRAQM ALWTVLAAPLLMSTDLRTISAQNMDILQNPLMIKINQDPLGIQGRRI HKEKSLIEVYMRPLSNKASALVFFSCRTDMPYRYHSSLGQLNFTGS VIYEAQDVYSGDIISGLRDETNFTVIINPSGVVMWYLYPIKNLEMSQ Q 292 MEAVAVAAAVGVLLLAGAGGAAGDEAREAAAVRALVARLLGPGP NAGLU AADFSVSVERALAAKPGLDTYSLGGGGAARVRVRGSTGVAAAAGL HRYLRDFCGCHVAWSGSQLRLPRPLPAVPGELTEATPNRYRYYQN VCTQSYSFVWWDWARWEREIDWMALNGINLALAWSGQEAIWQR VYLALGLTQAEINEFFTGPAFLAWGRMGNLHTWDGPLPPSWHIKQL YLQHRVLDQMRSFGMTPVLPAFAGHVPEAVTRVFPQVNVTKMGS WGHFNCSYSCSFLLAPEDPIFPIIGSLFLRELIKEFGTDHIYGADTFNE MQPPSSEPSYLAAATTAVYEAMTAVDTEAVWLLQGWLFQHQPQF WGPAQIRAVLGAVPRGRLLVLDLFAESQPVYTRTASFQGQPFIWCM LHNFGGNHGLFGALEAVNGGPEAARLFPNSTMVGTGMAPEGISQN EVVYSLMAELGWRKDPVPDLAAWVTSFAARRYGVSHPDAGAAWR LLLRSVYNCSGEACRGHNRSPLVRRPSLQMNTSIWYNRSDVFEAWR LLLTSAPSLATSPAFRYDLLDLTRQAVQELVSLYYEEARSAYLSKEL ASLLRAGGVLAYELLPALDEVLASDSRFLLGSWLEQARAAAVSEAE ADFYEQNSRYQLTLWGPEGNILDYANKQLAGLVANYYTPRWRLFL EALVDSVAQGIPFQQHQFDKNVFQLEQAFVLSKQRYPSQPRGDTVD LAKKIFLKYYPRWVAGSW 293 MTGERPSTALPDRRWGPRILGFWGGCRVWVFAAIFLLLSLAASWSK NEU1 AENDFGLVQPLVTMEQLLWVSGRQIGSVDTFRIPLITATPRGTLLAF AEARKMSSSDEGAKFIALRRSMDQGSTWSPTAFIVNDGDVPDGLNL GAVVSDVETGVVFLFYSLCAHKAGCQVASTMLVWSKDDGVSWST PRNLSLDIGTEVFAPGPGSGIQKQREPRKGRLIVCGHGTLERDGVFC LLSDDHGASWRYGSGVSGIPYGQPKQENDFNPDECQPYELPDGSVV INARNQNNYHCHCRIVLRSYDACDTLRPRDVTFDPELVDPVVAAGA VVTSSGIVFFSNPAHPEFRVNLTLRWSFSNGTSWRKET VQLWPGPSGYSSLATLEGSMDGEEQAPQLYVLYEKGRNHYTESISV AKISVYGTL 294 MTARGLALGLLLLLLCPAQVFSQSCVWYGECGIAYGDKRYNCEYS NPC1 GPPKPLPKDGYDLVQELCPGFFFGNVSLCCDVRQLQTLKDNLQLPL QFLSRCPSCFYNLLNLFCELTCSPRQSQFLNVTATEDYVDPVTNQTK TNVKELQYYVGQSFANAMYNACRDVEAPSSNDKALGLLCGKDAD ACNATNWIEYMFNKDNGQAPFTITPVFSDFPVHGMEPMNNATKGC DESVDEVTAPCSCQDCSIVCGPKPQPPPPPAPWTILGLDAMYVIMWI TYMAFLLVFFGAFFAVWCYRKRYFVSEYTPIDSNIAFSVNASDKGE ASCCDPVSAAFEGCLRRLFTRWGSFCVRNPGCVIFFSLVFITACSSGL VFVRVTTNPVDLWSAPSSQARLEKEYFDQHFGPFFRTEQLIIRAPLT DKHIYQPYPSGADVPFGPPLDIQILHQVLDLQIAIENITASYDNETVT LQDICLAPLSPYNTNCTILSVLNYFQNSHSVLDHKKGDDFFVYADY HTHFLYCVRAPASLNDTSLLHDPCLGTFGGPVFPWLVLGGYDDQN YNNATALVITFPVNNYYNDTEKLQRAQAWEKEFINFVKNYKNPNL TISFTAERSIEDELNRESDSDVFTVVISYAIMFLYISLALGHMKSCRRL LVDSKVSLGIAGILIVLSSVACSLGVFSYIGLPLTLIVIEVIPFLVLAVG VDNIFILVQAYQRDERLQGETLDQQLGRVLGEVAPSMFLSSFSETVA FFLGALSVMPAVHTFSLFAGLAVFIDFLLQITCFV SLLGLDIKRQEKNRLDIFCCVRGAEDGTSVQASESCLFRFFKNSYSPL LLKDWMRPIVIAIFVGVLSFSIAVLNKVDIGLDQSLSMPDDSYMVDY FKSISQYLHAGPPVYFVLEEGHDYTSSKGQNMVCGGMGCNNDSLV QQIFNAAQLDNYTRIGFAPSSWIDDYFDWVKPQSSCCRVDNITDQFC NASVVDPACVRCRPLTPEGKQRPQGGDFMRFLPMFLSDNPNPKCG KGGHAAYSSAVNILLGHGTRVGATYFMTYHTVLQTSADFIDALKK ARLIASNVTETMGINGSAYRVFPYSVFYVFYEQYLTIIDDTIFNLGVS LGAIFLVTMVLLGCELWSAVIMCATIAMVLVNMFGVMWLWGISLN AVSLVNLVMSCGISVEFCSHITRAFTVSMKGSRVERAEEALAHMGS SVFSGITLTKFGGIVVLAFAKSQIFQIFYFRMYLAMVLLGATHGLIFL PVLLSYIGPSVNKAKSCATEERYKGTERERLLNF 295 MRFLAATFLLLALSTAAQAEPVQFKDCGSVDGVIKEVNVSPCPTQP NPC2 CQLSKGQSYSVNVTFTSNIQSKSSKAVVHGILMGVPVPFPIPEPDGC KSGINCPIQKDKTYSYLNKLPVKSEYPSIKLVVEWQLQDDKNQSLFC WEIPVQIVSHL 296 MSCPVPACCALLLVLGLCRARPRNALLLLADDGGFESGAYNNSAIA SGSH TPHLDALARRSLLFRNAFTSVSSCSPSRASLLTGLPQHQNGMYGLH QDVHHFNSFDKVRSLPLLLSQAGVRTGIIGKKHVGPETVYPFDFAYT EENGSVLQVGRNITRIKLLVRKFLQTQDDRPFFLYVAFHDPHRCGHS QPQYGTFCEKFGNGESGMGRIPDWTPQAYDPLDVLVPYFVPNTPAA RADLAAQYTTVGRMDQGVGLVLQELRDAGVLNDTLVIFTSDNGIPF PSGRTNLYWPGTAEPLLVSSPE HPKRWGQVSEAYVSLLDLTPTILDWFSIPYPSYAIFGSKTIHLTGRSL LPALEAEPLWATVFGSQSHHEVTMSYPMRSVQHRHFRLVHNLNFK MPFPIDQDFYVSPTFQDLLNRTTAGQPTGWYKDLRHYYYRARWEL YDRSRDPHETQNLATDPRFAQLLEMLRDQLAKWQWETHDPWVCA PDGVLEEKLSPQCQPLHNEL 297 MASPGCLWLLAVALLPWTCASRALQHLDPPAPLPLVIWHGMGDSC PPT1 CNPLSMGAIKKMVEKKIPGIYVLSLEIGKTLMEDVENSFFLNVNSQV TTVCQALAKDPKLQQGYNAMGFSQGGQFLRAVAQRCPSPPMINLIS VGGQHQGVFGLPRCPGESSHICDFIRKTLNAGAYSKVVQERLVQAE YWHDPIKEDVYRNHSIFLADINQERGINESYKKNLMALKKFVMVKF LNDSIVDPVDSEWFGFYRSGQAKETIPLQETSLYTQDRLGLKEMDN AGQLVFLATEGDHLQLSEEWFYAHIIPFLG 298 MYALFLLASLLGAALAGPVLGLKECTRGSAVWCQNVKTASDCGA PSAP VKHCLQTVWNKPTVKSLPCDICKDVVTAAGDMLKDNATEEEILVY LEKTCDWLPKPNMSASCKEIVDSYLPVILDIIKGEMSRPGEVCSALN LCESLQKHLAELNHQKQLESNKIPELDMTEVVAPFMANIPLLLYPQ DGPRSKPQPKDNGDVCQDCIQMVTDIQTAVRTNSTFVQALVEHVK EECDRLGPGMADICKNYISQYSEIAIQMMMHMQPKEICALVGFCDE VKEMPMQTLVPAKVASKNVIPALELVEPIKKHEVPAKSDVYCEVCE FLVKEVTKLIDNNKTEKEILDAFDKMCSKLPKSLSEECQEVVDTYGS SILSILLEEVSPELVCSMLHLCSGTRLPALTVHVTQPKDGGFCEVCK KLVGYLDRNLEKNSTKQEILAALEKGCSFLPDPYQKQCDQFVAEYE PVLIEILVEVMDPSFVCLKIGACPSAHKPLLGTEKCIWGPSYWCQNT ETAAQCNAVEHCKRHVWN 299 MRSPVRDLARNDGEESTDRTPLLPGAPRAEAAPVCCSARYNLAILA SLC17A5 FFGFFIVYALRVNLSVALVDMVDSNTTLEDNRTSKACPEHSAPIKVH HNQTGKKYQWDAETQGWILGSFFYGYIITQIPGGYVASKIGGKMLL GFGILGTAVLTLFTPIAADLGVGPLIVLRALEGLGEGVTFPAMHAM WSSWAPPLERSKLLSISYAGAQLGTVISLPLSGIICYYMNWTYVFYF FGTIGIFWFLLWIWLVSDTPQKHKRISHYEKEYILSSLRNQLSSQKSV PWVPILKSLPLWAIVVAHFSYNWTFYTLLTLLPTYMKEILRFNVQEN GFLSSLPYLGSWLCMILSGQAADNLRAKWNFSTLCVRRIFSLIGMIG PAVFLVAAGFIGCDYSLAVAFLTISTTLGGFCSSGFSINHLDIAPSYA GILLGITNTFATIPGMVGPVIAKSLTPDNTVGEWQTVFYIAAAINVFG AIFFTLFAKGEVQNWALNDHHGHRH 300 MPRYGASLRQSCPRSGREQGQDGTAGAPGLLWMGLVLALALALAL SMPD1 ALALSDSRVLWAPAEAHPLSPQGHPARLHRIVPRLRDVFGWGNLTC PICKGLFTAINLGLKKEPNVARVGSVAIKLCNLLKIAPPAVCQSIVHL FEDDMVEVWRRSVLSPSEACGLLLGSTCGHWDIFSSWNISLPTVPKP PPKPPSPPAPGAPVSRILFLTDLHWDHDYLEGTDPDCADPLCCRRGS GLPPASRPGAGYWGEYSKCDLPLRTLESLLSGLGPAGPFDMVYWT GDIPAHDVWHQTRQDQLRALTTVTALVRKFLGPVPVYPAVGNHES TPVNSFPPPFIEGNHSSRWLYEAMAKAWEPWLPAEALRTLRIGGFY ALSPYPGLRLISLNMNFCSRENFWLLINSTDPAGQLQWLVGELQAA EDRGDKVHIIGHIPPGHCLKSWSWNYYRIVARYENTLAAQFFGHTH VDEFEVFYDEETLSRPLAVAFLAPSATTYIGLNPGYRVYQIDGNYSG SSHVVLDHETYILNLTQANIPGAIPHWQLLYRARETYGLPNTLPTAW HNLVYRMRGDMQLFQTFWFLYHKGHPPSEPCGTPCRLATLCAQLS ARADSPALCRHLMPDGSLPEAQSLWPRPLFC 301 MAAPALGLVCGRCPELGLVLLLLLLSLLCGAAGSQEAGTGAGAGSL SUMF1 AGSCGCGTPQRPGAHGSSAAAHRYSREANAPGPVPGERQLAHSKM VPIPAGVFTMGTDDPQIKQDGEAPARRVTIDAFYMDAYEVSNTEFE KFVNSTGYLTEAEKFGDSFVFEGMLSEQVKTNIQQAVAAAPWWLP VKGANWRHPEGPDSTILHRPDHPVLHVSWNDAVAYCTWAGKRLP TEAEWEYSCRGGLHNRLFPWGNKLQPKGQHYANIWQGEFPVTNTG EDGFQGTAPVDAFPPNGYGLYNIVGNAWEWTSDWWTVHHSVEET LNPKGPPSGKDRVKKGGSYMCHRSYCYRYRCAARSQNTPDSSASN LGFRCAADRLPTMD 302 MGLQACLLGLFALILSGKCSYSPEPDQRRTLPPGWVSLGRADPEEEL TPP1 SLTFALRQQNVERLSELVQAVSDPSSPQYGKYLTLENVADLVRPSPL TLHTVQKWLLAAGAQKCHSVITQDFLTCWLSIRQAELLLPGAEFHH YVGGPTETHVVRSPHPYQLPQALAPHVDFVGGLHRFPPTSSLRQRPE PQVTGTVGLHLGVTPSVIRKRYNLTSQDVGSGTSNNSQACAQFLEQ YFHDSDLAQFMRLFGGNFAHQASVARVVGQQGRGRAGIEASLDVQ YLMSAGANISTWVYSSPGRHEG QEPFLQWLMLLSNESALPHVHTVSYGDDEDSLSSAYIQRVNTELMK AAARGLTLLFASGDSGAGCWSVSGRHQFRPTFPASSPYVTTVGGTS FQEPFLITNEIVDYISGGGFSNVFPRPSYQEEAVTKFLSSSPHLPPSSYF NASGRAYPDVAALSDGYWVVSNRVPIPWVSGTSASTPVFGGILSLIN EHRILSGRPPLGFLNPRLYQQHGAGLFDVTRGCHESCLDEEVEGQGF CSGPGWDPVTGWGTPNFPALLKTLLNP 303 MSDKLPYKVADIGLAAWGRKALDIAENEMPGLMRMRERYSASKPL AHCY KGARIAGCLHMTVETAVLIETLVTLGAEVQWSSCNIFSTQDHAAAAI AKAGIPVYAWKGETDEEYLWCIEQTLYFKDGPLNMILDDGGDLTN LIHTKYPQLLPGIRGISEETTTGVHNLYKMMANGILKVPAINVNDSV TKSKFDNLYGCRESLIDGIKRATDVMIAGKVAVVAGYGDVGKGCA QALRGFGARVIITEIDPINALQAAMEGYEVTTMDEACQEGNIFVTTT GCIDIILGRHFEQMKDDAIVCNIG HFDVEIDVKWLNENAVEKVNIKPQVDRYRLKNGRRIILLAEGRLVN LGCAMGHPSFVMSNSFTNQVMAQIELWTHPDKYPVGVHFLPKKLD EAVAEAHLGKLNVKLTKLTEKQAQYLGMSCDGPFKPDHYRY 304 MVDSVYRTRSLGVAAEGLPDQYADGEAARVWQLYIGDTRSRTAEY GNMT KAWLLGLLRQHGCQRVLDVACGTGVDSIMLVEEGFSVTSVDASDK MLKYALKERWNRRHEPAFDKWVIEEANWMTLDKDVPQSAEGGFD AVICLGNSFAHLPDCKGDQSEHRLALKNIASMVRAGGLLVIDHRNY DHILSTGCAPPGKNIYYKSDLTKDVTTSVLIVNNKAHMVTLDYTVQ VPGAGQDGSPGLSKFRLSYYPHCLASFTELLQAAFGGKCQHSVLGD FKPYKPGQTYIPCYFIHVLKRTD 305 MNGPVDGLCDHSLSEGVFMFTSESVGEGHPDKICDQISDAVLDAHL MAT1A KQDPNAKVACETVCKTGMVLLCGEITSMAMVDYQRVVRDTIKHIG YDDSAKGFDFKTCNVLVALEQQSPDIAQCVHLDRNEEDVGAGDQG LMFGYATDETEECMPLTIILAHKLNARMADLRRSGLLPWLRPDSKT QVTVQYMQDNGAVIPVRIHTIVISVQHNEDITLEEMRRALKEQVIRA VVPAKYLDEDTVYHLQPSGRFVIGGPQGDAGVTGRKIIVDTYGGW GAHGGGAFSGKDYTKVDRSAAYAARWVAKSLVKAGLCRRVLVQ VSYAIGVAEPLSISIFTYGTSQKTERELLDVVHKNFDLRPGVIVRDLD LKKPIYQKTACYGHFGRSEFPWEVPRKLVF 306 MEKGPVRAPAEKPRGARCSNGFPERDPPRPGPSRPAEKPPRPEAKSA GCH1 QPADGWKGERPRSEEDNELNLPNLAAAYSSILSSLGENPQRQGLLK TPWRAASAMQFFTKGYQETISDVLNDAIFDEDHDEMVIVKDIDMFS MCEHHLVPFVGKVHIGYLPNKQVLGLSKLARIVEIYSRRLQVQERL TKQIAVAITEALRPAGVGVVVEATHMCMVMRGVQKMNSKTVTST MLGVFREDPKTREEFLTLIRS 307 MAGKAHRLSAEERDQLLPNLRAVGWNELEGRDAIFKQFHFKDFNR PCBD1 AFGFMTRVALQAEKLDHHPEWFNVYNKVHITLSTHECAGLSERDIN LASFIEQVAVSMT 308 MSTEGGGRRCQAQVSRRISFSASHRLYSKFLSDEENLKLFGKCNNP PTS NGHGHNYKVVVTVHGEIDPATGMVMNLADLKKYMEEAIMQPLDH KNLDMDVPYFADVVSTTENVAVYIWDNLQKVLPVGVLYKVKVYE TDNNIVVYKGE 309 MAAAAAAGEARRVLVYGGRGALGSRCVQAFRARNWWVASVDVV QDPR ENEEASASIIVKMTDSFTEQADQVTAEVGKLLGEEKVDAILCVAGG WAGGNAKSKSLFKNCDLMWKQSIWTSTISSHLATKHLKEGGLLTL AGAKAALDGTPGMIGYGMAKGAVHQLCQSLAGKNSGMPPGAAAI AVLPVTLDTPMNRKSMPEADFSSWTPLEFLVETFHDWITGKNRPSS GSLIQVVTTEGRTELTPAYF 310 MEGGLGRAVCLLTGASRGFGRTLAPLLASLLSPGSVLVLSARNDEA SPR LRQLEAELGAERSGLRVVRVPADLGAEAGLQQLLGALRELPRPKGL QRLLLINNAGSLGDVSKGFVDLSDSTQVNNYWALNLTSMLCLTSSV LKAFPDSPGLNRTVVNISSLCALQPFKGWALYCAGKAARDMLFQV LALEEPNVRVLNYAPGPLDTDMQQLARETSVDPDMRKGLQELKAK GKLVDCKVSAQKLLSLLEKDEFKSGAHVDFYDK 311 MDAILNYRSEDTEDYYTLLGCDELSSVEQILAEFKVRALECHPDKHP DNAJC12 ENPKAVETFQKLQKAKEILTNEESRARYDHWRRSQMSMPFQQWEA LNDSVKTSMHWVVRGKKDLMLEESDKTHTTKMENEECNEQRERK KEELASTAEKTEQKEPKPLEKSVSPQNSDSSGFADVNGWHLRFRWS KDAPSELLRKFRNYEI 312 MLLPAPALRRALLSRPWTGAGLRWKHTSSLKVANEPVLAFTQGSPE ALDH4A1 RDALQKALKDLKGRMEAIPCVVGDEEVWTSDVQYQVSPFNHGHK VAKFCYADKSLLNKAIEAALAARKEWDLKPIADRAQIFLKAADMLS GPRRAEILAKTMVGQGKTVIQAEIDAAAELIDFFRFNAKYAVELEG QQPISVPPSTNSTVYRGLEGFVAAISPFNFTAIGGNLAGAPALMGNV VLWKPSDTAMLASYAVYRILREAGLPPNIIQFVPADGPLFGDTVTSS EHLCGINFTGSVPTFKHLWKQVAQ NLDRFHTFPRLAGECGGKNFHFVHRSADVESVVSGTLRSAFEYGGQ KCSACSRLYVPHSLWPQIKGRLLEEHSRIKVGDPAEDFGTFFSAVID AKSFARIKKWLEHARSSPSLTILAGGKCDDSVGYFVEPCIVESKDPQ EPIMKEEIFGPVLSVYVYPDDKYKETLQLVDSTTSYGLTGAVFSQDK DVVQEATKVLRNAAGNFYINDKSTGSIVGQQPFGGARASGTNDKP GGPHYILRWTSPQVIKETHKPLGDWSYAYMQ 313 MALRRALPALRPCIPRFVQLSTAPASREQPAAGPAAVPGGGSATAV PRODH RPPVPAVDFGNAQEAYRSRRTWELARSLLVLRLCAWPALLARHEQ LLYVSRKLLGQRLFNKLMKMTFYGHFVAGEDQESIQPLLRHYRAFG VSAILDYGVEEDLSPEEAEHKEMESCTSAAERDGSGTNKRDKQYQA HRAFGDRRNGVISARTYFYANEAKCDSHMETFLRCIEASGRVSDDG FIAIKLTALGRPQFLLQFSEVLAKWRCFFHQMAVEQGQAGLAAMDT KLEVAVLQESVAKLGIASRAEIEDW FTAETLGVSGTMDLLDWSSLIDSRTKLSKHLVVPNAQTGQLEPLLSR FTEEEELQMTRMLQRMDVLAKKATEMGVRLMVDAEQTYFQPAISR LTLEMQRKFNVEKPLIFNTYQCYLKDAYDNVTLDVELARREGWCF GAKLVRGAYLAQERARAAEIGYEDPINPTYEATNAMYHRCLDYVL EELKHNAKAKVMVASHNEDTVRFALRRMEELGLHPADHQVYFGQ LLGMCDQISFPLGQAGYPVYKYVPYGPVMEVLPYLSRRALENSSLM KGTHRERQLLWLELLRRLRTGNLFHRPA 314 MTTYSDKGAKPERGRFLHFHSVTFWVGNAKQAASFYCSKMGFEPL HPD AYRGLETGSREVVSHVIKQGKIVFVLSSALNPWNKEMGDHLVKHG DGVKDIAFEVEDCDYIVQKARERGAKIMREPWVEQDKFGKVKFAV LQTYGDTTHTLVEKMNYIGQFLPGYEAPAFMDPLLPKLPKCSLEMI DHIVGNQPDQEMVSASEWYLKNLQFHRFWSVDDTQVHTEYSSLRSI VVANYEESIKMPINEPAPGKKKSQIQEYVDYNGGAGVQHIALKTEDI ITAIRHLRERGLEFLSVPSTYYKQLREKLKTAKIKVKENIDALEELKI LVDYDEKGYLLQIFTKPVQDRPTLFLEVIQRHNHQGFGAGNFNSLF KAFEEEQNLRGNLTNMETNGVVPGM 315 MEFSSPSREECPKPLSRVSIMAGSLTGLLLLQAVSWASGARPCIPKSF GBA GYSSVVCVCNATYCDSFDPPTFPALGTFSRYESTRSGRRMELSMGPI QANHTGTGLLLTLQPEQKFQKVKGFGGAMTDAAALNILALSPPAQ NLLLKSYFSEEGIGYNIIRVPMASCDFSIRTYTYADTPDDFQLHNFSL PEEDTKLKIPLIHRALQLAQRPVSLLASPWTSPTWLKTNGAVNGKGS LKGQP GDIYHQTWARYFVKFLDAYAEHKLQFWAVTAENEPSAGLLSGYPF QCLGFTPEHQRDFIARDLGPTLANSTHHNVRLLMLDDQRLLLPHWA KVVLTDPEAAKYVHGIAVHWYLDFLAPAKATLGETHRLFPNTMLF ASEACVGSKFWEQSVRLGSWDRGMQYSHSIITNLLYHVVGWTDW NLALNPEGGPNWVRNFVDSPIIVDITKDTFYKQPMFYHLGHFSKFIP EGSQRVGLVASQKNDLDAVALMHPDGSAVVVVLNRSSKDVPLTIK DPAVGFLETISPGYSIHTYLWRRQ 316 MAELKYISGFGNECSSEDPRCPGSLPEGQNNPQVCPYNLYAEQLSGS HGD AFTCPRSTNKRSWLYRILPSVSHKPFESIDEGQVTHNWDEVDPDPNQ LRWKPFEIPKASQKKVDFVSGLHTLCGAGDIKSNNGLAIHIFLCNTS MENRCFYNSDGDFLIVPQKGNLLIYTEFGKMLVQPNEICVIQRGMRF SIDVFEETRGYILEVYGVHFELPDLGPIGANGLANPRDFLIPIAWYED RQVPGGYTVINKYQGKLFAAKQDVSPFNVVAWHGNYTPYKYNLK NFMVINSVAFDHADPSIFTVLTAKSVRPGVAIADFVIFPPRWGVADK TFRPPYYHRNCMSEFMGLIRGHYEAKQGGFLPGGGSLHSTMTPHGP DADCFEKASKVKLAPERIADGTMAFMFESSLSLAVTKWGLKASRCL DENYHKCWEPLKSHFTPNSRNPAEPN 317 MGVLGRVLLWLQLCALTQAVSKLWVPNTDFDVAANWSQNRTPCA AMN GGAVEFPADKMVSVLVQEGHAVSDMLLPLDGELVLASGAGFGVSD VGSHLDCGAGEPAVFRDSDRFSWHDPHLWRSGDEAPGLFFVDAER VPCRHDDVFFPPSASFRVGLGPGASPVRVRSISALGRTFTRDEDLAV FLASRAGRLRFHGPGALSVGPEDCADPSGCVCGNAEAQPWICAALL QPLGGRCPQAACHSALRPQGQCCDLCGAVVLLTHGPAFDLERYRA RILDTFLGLPQYHGLQVAVSKVPRSSRLREADTEIQVVLVENGPETG GAGRLARALLADVAENGEALGVLEATMRESGAHVWGSSAAGLAG GVAAAVLLALLVLLVAPPLLRRAGRLRWRRHEAAAPAGAPLGFRN PVFDVTASEELPLPRRLSLVPKAAADSTSHSYFVNPLFAGAEAEA 318 MSGGWMAQVGAWRTGALGLALLLLLGLGLGLEAAASPLSTPTSAQ CD320 AAGPSSGSCPPTKFQCRTSGLCVPLTWRCDRDLDCSDGSDEEECRIE PCTQKGQCPPPPGLPCPCTGVSDCSGGTDKKLRNCSRLACLAGELR CTLSDDCIPLTWRCDGHPDCPDSSDELGCGTNEILPEGDATTMGPPV TLESVTSLRNATTMGPPVTLESVPSVGNATSSSAGDQSGSPTAYGVI AAAAVLSASLVTATLLLLSWLRAQERLRPLGLLVAMKESLLLSEQK TSLP 319 MMNMSLPFLWSLLTLLIFAEVNGEAGELELQRQKRSINLQQPRMAT CUBN ERGNLVFLTGSAQNIEFRTGSLGKIKLNDEDLSECLHQIQKNKEDIIE LKGSAIGLPQNISSQIYQLNSKLVDLERKFQGLQQTVDKKVCSSNPC QNGGTCLNLHDSFFCICPPQWKGPLCSADVNECEIYSGTPLSCQNGG TCVNTMGSYSCHCPPETYGPQCASKYDDCEGGSVARCVHGICEDL MREQAGEPKYSCVCDAGWMFSPNSPACTLDRDECSFQPGPCSTLV QCFNTQGSFYCGACPTGWQGNGYICEDINECEINNGGCSVAPPVEC VNTPGSSHCQACPPGYQGDGRVCTLTDICSVSNGGCHPDASCSSTL GSLPLCTCLPGYTGNGYGPNGCVQLSNICLSHPCLNGQCIDTVSGYF CKCDSGWTGVNCTENINECLSNPCLNGGTCVDGVDSFSCECTRLWT GALCQVPQQVCGESLSGINGSFSYRSPDVGYVHDVNCFWVIKTEMG KVLRITFTFFRLESMDNCPHEFLQVYDGDSSSAFQLGRFCGSSLPHE LLSSDNALYFHLYSEHLRNGRGFTVRWETQQPECGGILTGPYGSIKS PGYPGNYPPGRDCVWIVVTSPDLLVTFTFGTLSLEHHDDCNKDYLEI RDGPLYQDPLLGKFCTTFSVPPLQTTGPFARIHFHSDSQISDQGFHIT YLTSPSDLRCGGNYTDPEGELFLPELSGPFTHTRQCVYMMKQPQGE QIQINFTHVELQCQSDSSQNYIEVRDGETLLGKVCGNGTISHIKSITN SVWIRFKIDASVEKASFRAVYQVACGDELTGEGVIRSPFFPNVYPGE RTCRWTIHQPQSQVILLNFTVFEIGSSAHCETDYVEIGSSSILGSPENK KYCGTDIPSFITSVYNFLYVTFVKSSSTENHGFMAKFSAEDLACGEIL TESTGTIQSPGHPNVYPHGINCTWHILVQPNHLIHLMFETFHLEFHY NCTNDYLEVYDTDSETSLGRYCGKSIPPSLTSSGNSL MLVFVTDSDLAYEGFLINYEAISAATACLQDYTDDLGTFTSPNFPNN YPNNWECIYRITVRTGQLIAVHFTNFSLEEAIGNYYTDFLEIRDGGYE KSPLLGIFYGSNLPPTIISHSNKLWLKFKSDQIDTRSGFSAYWDGSST GCGGNLTTSSGTFISPNYPMPYYHSSECYWWLKSSHGSAFELEFKDF HLEHHPNCTLDYLAVYDGPSSNSHLLTQLCGDEKPPLIRSSGDSMFI KLR TDEGQQGRGFKAEYRQTCENVVIVNQTYGILESIGYPNPYSENQHC NWTIRATTGNTVNYTFLAFDLEHHINCSTDYLELYDGPRQMGRYCG VDLPPPGSTTSSKLQVLLLTDGVGRREKGFQMQWFVYGCGGELSG ATGSFSSPGFPNRYPPNKECIWYIRTDPGSSIQLTIHDFDVEYHSRCN FDVLEIYGGPDFHSPRIAQLCTQRSPENPMQVSSTGNELAIRFKTDLS INGRGFNASWQAVTGGCGGIFQAPSGEIHSPNYPSPYRSNTDCSWVI RVDRNHRVLLNFTDFDLEPQDSCIMAYDGLSSTMSRLARTCGREQL ANPIVSSGNSLFLRFQSGPSRQNRGFRAQFRQACGGHILTSSFDTVSS PRFPANYPNNQNCSWIIQAQPPLNHITLSFTHFELERSTTCARDFVEIL DGGHEDAPLRGRYCGTDMPHPITSFSSALTLRFVSDSSISAGGFHTT VTASVSACGGTFYMAEGIFNSPGYPDIYPPNVECVWNIVSSPGNRLQ LSFISFQLEDSQDCSRDFVEIREGNATGHLVGRYCGNSFPLNYSSIVG HTLWVRFISDGSGSGTGFQATFMKIFGNDNIVGTHGKVASPFWPEN YPHNSNYQWTVNVNASHVVHGRILEMDIEEIQNCYYDKLRIYDGPS IHARLIGAYCGTQTESFSSTGNSLTFHFYSDSSISGKGFLLEWFAVDA PDGVLPTIAPGACGGFLRTGDAPVFLFSPGWPDSYSNRVDCTWLIQ APDSTVELNILSLDIESHRTCAYDSLVIRDGDNNLAQQLAVLCGREIP GPIRSTGEYMFIRFTSDSSVTRAGFNASFHKSCGGYLHADRGIITSPK YPETYPSNLNCSWHVLVQSGLTIAVHFEQPFQIPNGDSSCNQGDYLV LRNGPDICSPPLGPPGGNGHFCGSHASSTLFTSDNQMFVQFISDHSNE GQGFKIKYEAKSLACGGNVYIHDADSAGYVTSPNHPHNYPPHADCI WILAAPPETRIQLQFEDRFDIEVTPNCTSNYLELRDGVDSDAPILSKF CGTSLPSSQWSSGEVMYLRFRSDNSPTHVGFKAKYSIAQCGGRVPG QSGVVESIGHPTLPYRDNLFCEWHLQGLSGHYLTISFEDFNLQNSSG CEKDFVEIWDNHTSGNILGRYCGNTIPDSIDTSSNTAVVRFVTDGSV TASGFRLRFESSMEECGGDLQGSIGTFTSPNYPNPNPHGRICEWRITA PEGRRITLMFNNLRLATHPSCNNEHVIVFNGIRSNSPQLEKLCSSVNV SNEIKSSGNTMKVIFFTDGSRPYGGFTASYTSSEDAVCGGSLPNTPE GNFTSPGYDGVRNYSRNLNCEWTLSNPNQGNSSISIHFEDFYLESHQ DCQFDVLEFRVGDADGPLMWRLCGPSKPTLPLVIPYSQVWIHFVTN ERVEHIGFHAKYSFTDCGGIQIGDSGVITSPNYPNAYDSLTHCSSLLE APQGHTITLTFSDFDIEPHTTCAWDSVTVRNGGSPESPIIGQYCGNSN PRTIQSGSNQLVVTFNSDHSLQGGGFYATWNTQTLGCGGIFHSDNG TIRSPHWPQNFPENSRCSWTAITHKSKHLEISFDNNFLIPSGDGQCQN SFVKVWAGTEEVDKALLATGCGNVAPGPVITPSNTFTAVFQSQEAP AQGFSASFVSRCGSNFTGPSGYIISPNYPKQYDNNMNCTYVIEANPL SVVLLTFVSFHLEARSAVTGSCVNDGVHIIRGYSVMSTPFATVCG DEMPAPLTIAGPVLLNFYSNEQITDFGFKFSYRIISCGGVFNFSSGIITS PAYSYADYPNDMHCLYTITVSDDKVIELKFSDFDVVPSTSCSHDYL AIYDGANTSDPLLGKFCGSKRPPNVKSSNNSMLLVFKTDSFQTAKG WKMSFRQTLGPQQGCGGYLTGSNNTFASPDSDSNGMYDKNLNCV WIIIAPVNKVIHLTFNTFALEAASTRQRCLYDYVKLYDGDSENANLA GTFCGSTVPAPFISSGNFLTVQFISDLTLEREGFNATYTIMDMPCGGT YNATWTPQNISSPNSSDPDVPFSICTWVIDSPPHQQVKITVWALQLT SQDCTQNYLQLQDSPQGHGNSRFQFCGRNASAVPVFYSSMSTAMVI FKSGVVNRNSRMSFTYQIADCNRDYHKAFGNLRSPGWPDNYDNDK DCTVTLTAPQNHTISLFFHSLGIENSVECRNDFLEVRNGSNSNSPLLG KYCGTLLPNPVFSQNNELYLRFKSDSVTSDRGYEIIWTSSPSGCGGT LYGDRGSFTSPGYPGTYPNNTYCEWVLVAPAGRLVTINFYFISIDDP GDCVQNYLTLYDGPNASSPSSGPYCGGDTSIAPFVASSNQVFIKFHA DYARRPSAFRLTWDS 320 MAWFALYLLSLLWATAGTSTQTQSSCSVPSAQEPLVNGIQVLMENS GIF VTSSAYPNPSILIAMNLAGAYNLKAQKLLTYQLMSSDNNDLTIGQL GLTIMALTSSCRDPGDKVSILQRQMENWAPSSPNAEASAFYGPSLAI LALCQKNSEATLPIAVRFAKTLLANSSPFNVDTGAMATLALTCMYN KIPVGSEEGYRSLFGQVLKDIVEKISMKIKDNGIIGDIYSTGLAMQAL SVTPEPSKKEWNCKKTTDMILNEIKQGKFHNPMSIAQILPSLKGKTY LDVPQVTCSPDHEVQPTLPSNPGPGPTSASNITVIYTINNQLRGVELL FNETINVSVKSGSVLLVVLEEAQRKNPMFKFETTMTSWGLVVSSIN NIAENVNHKTYWQFLSGVTPLNEGVADYIPFNHEHITANFTQY 321 MRQSHQLPLVGLLLFSFIPSQLCEICEVSEENYIRLKPLLNTMIQSNY TCN1 NRGTSAVNVVLSLKLVGIQIQTLMQKMIQQIKYNVKSRLSDVSSGE LALIILALGVCRNAEENLIYDYHLIDKLENKFQAEIENMEAHNGTPL TNYYQLSLDVLALCLFNGNYSTAEVVNHFTPENKNYYFGSQFSVDT GAMAVLALTCVKKSLINGQIKADEGSLKNISIYTKSLVEKILSEKKE NGLIGN TFSTGEAMQALFVSSDYYNENDWNCQQTLNTVLTEISQGAFSNPNA AAQVLPALMGKTFLDINKDSSCVSASGNFNISADEPITVTPPDSQSYI SVNYSVRINETYFTNVTVLNGSVFLSVMEKAQKMNDTIFGFTMEER SWGPYITCIQGLCANNNDRTYWELLSGGEPLSQGAGSYVVRNGENL EVRWSKY 322 MRHLGAFLFLLGVLGALTEMCEIPEMDSHLVEKLGQHLLPWMDRL TCN2 SLEHLNPSIYVGLRLSSLQAGTKEDLYLHSLKLGYQQCLLGSAFSED DGDCQGKPSMGQLALYLLALRANCEFVRGHKGDRLVSQLKWFLE DEKRAIGHDHKGHPHTSYYQYGLGILALCLHQKRVHDSVVDKLLY AVEPFHQGHHSVDTAAMAGLAFTCLKRSNFNPGRRQRITMAIRTVR EEILKAQTPEGHFGNVYSTPLALQFLMTSPMRGAELGTACLKARVA LLASLQDGAFQNALMISQLLPVLNHKTYIDLIFPDCLAPRVMLEPAA ETIPQTQEIISVTLQVLSLLPPYRQSISVLAGSTVEDVLKKAHELGGFT YETQASLSGPYLTSVMGKAAGEREFWQLLRDPNTPLLQGIADYRPK DGETIELRLVSW 323 MQQKTKLFLQALKYSIPHLGKCMQKQHLNHYNFADHCYNRIKLKK PREPL YHLTKCLQNKPKISELARNIPSRSFSCKDLQPVKQENEKPLPENMDA FEKVRTKLETQPQEEYEIINVEVKHGGFVYYQEGCCLVRSKDEEAD NDNYEVLFNLEELKLDQPFIDCIRVAPDEKYVAAKIRTEDSEASTCVI IKLSDQPVMEASFPNVSSFEWVKDEEDEDVLFYTFQRNLRCHDVYR ATFGDNKRNERFYTEKDPSYFVFLYLTKDSRFLTINIMNKTTSEVWL IDGLSPWDPPVLIQKRIHGVLYYVEHRDDELYILTNVGEPTEFKLMR TAADTPAIMNWDLFFTMKRNTKVIDLDMFKDHCVLFLKHSNLLYV NVIGLADDSVRSLKLPPWACGFIMDTNSDPKNCPFQLCSPIRPPKYY TYKFAEGKLFEETGHEDPITKTSRVLRLEAKSKDGKLVPMTVFHKT DSEDLQKKPLLVHVYGAYGMDLKMNFRPERRVLVDDGWILAYCH VRGGGELGLQWHADGRLTKKLNGLADLEACIKTLHGQGFSQPSLT TLTAFSAGGVLAGALCNSNPELVRAVTLEAPFLDVLNTMMDTTLPL T LEELEEWGNPSSDEKHKNYIKRYCPYQNIKPQHYPSIHITAYENDER VPLKGIVSYTEKLKEAIAEHAKDTGEGYQTPNIILDIQPGGNHVIEDS HKKITAQIKFLYEELGLDSTSVFEDLKKYLKF 324 MAFANLRKVLISDSLDPCCRKILQDGGLQVVEKQNLSKEELIAELQD PHGDH CEGLIVRSATKVTADVINAAEKLQVVGRAGTGVDNVDLEAATRKGI LVMNTPNGNSLSAAELTCGMIMCLARQIPQATASMKDGKWERKKF MGTELNGKTLGILGLGRIGREVATRMQSFGMKTIGYDPIISPEVSASF GVQQLPLEEIWPLCDFITVHTPLLPSTTGLLNDNTFAQCKKGVRVVN CARGGIVDEGALLRALQSGQCAGAALDVFTEEPPRDRALVDHENVI SCPHLGASTKEAQSRCGEEIA VQFVDMVKGKSLTGVVNAQALTSAFSPHTKPWIGLAEALGTLMRA WAGSPKGTIQVITQGTSLKNAGNCLSPAVIVGLLKEASKQADVNLV NAKLLVKEAGLNVTTSHSPAAPGEQGFGECLLAVALAGAPYQAVG LVQGTTPVLQGLNGAVFRPEVPLRRDLPLLLFRTQTSDPAMLPTMIG LLAEAGVRLLSYQTSLVSDGETWHVMGISSLLPSLEAWKQHVTEAF QFHF 325 MDAPRQVVNFGPGPAKLPHSVLLEIQKELLDYKGVGISVLEMSHRS PSAT1 SDFAKIINNTENLVRELLAVPDNYKVIFLQGGGCGQFSAVPLNLIGL KAGRCADYVVTGAWSAKAAEEAKKFGTINIVHPKLGSYTKIPDPST WNLNPDASYVYYCANETVHGVEFDFIPDVKGAVLVCDMSSNFLSK PVDVSKFGVIFAGAQKNVGSAGVTVVIVRDDLLGFALRECPSVLEY KVQAGNSSLYNTPPCFSIYVMGLVLEWIKNNGGAAAMEKLSSIKSQ TIYEIIDNSQGFYVCPVEPQNRSKMNIPFRIGNAKGDDALEKRFLDK ALELNMLSLKGHRSVGGIRASLYNAVTIEDVQKLAAFMKKFLEMH QL 326 MVSHSELRKLFYSADAVCFDVDSTVIREEGIDELAKICGVEDAVSE PSPH MTRRAMGGAVPFKAALTERLALIQPSREQVQRLIAEQPPHLTPGIRE LVSRLQERNVQVFLISGGFRSIVEHVASKLNIPATNVFANRLKFYFN GEYAGFDETQPTAESGGKGKVIKLLKEKFHFKKIIMIGDGATDMEA CPPADAFIGFGGNVIRQQVKDNAKWYITDFVELLGELEE 327 MQRAVSVVARLGFRLQAFPPALCRPLSCAQEVLRRTPLYDFHLAHG AMT GKMVAFAGWSLPVQYRDSHTDSHLHTRQHCSLFDVSHMLQTKILG SDRVKLMESLVVGDIAELRPNQGTLSLFTNEAGGILDDLIVTNTSEG HLYVVSNAGCWEKDLALMQDKVRELQNQGRDVGLEVLDNALLAL QGPTAAQVLQAGVADDLRKLPFMTSAVMEVFGVSGCRVTRCGYT GEDGVEISVPVAGAVHLATAILKNPEVKLAGLAARDSLRLEAGLCL YGNDIDEHTTPVEGSLSWTLGKRRRAAMDFPGAKVIVPQLKGRVQ RRRVGLMCEGAPMRAHSPILNMEGTKIGTVTSGCPSPSLKKNVAMG YVPCEYSRPGTMLLVEVRRKQQMAVVSKMPFVPTNYYTLK 328 MALRVVRSVRALLCTLRAVPSPAAPCPPRPWQLGVGAVRTLRTGP GCSH ALLSVRKFTEKHEWVTTENGIGTVGISNFAQEALGDVVYCSLPEVG TKLNKQDEFGALESVKAASELYSPLSGEVTEINEALAENPGLVNKSC YEDGWLIKMTLSNPSELDELMSEEAYEKYIKSIEE 329 MQSCARAWGLRLGRGVGGGRRLAGGSGPCWAPRSRDSSSGGGDS GLDC AAAGASRLLERLLPRHDDFARRHIGPGDKDQREMLQTLGLASIDELI EKTVPANIRLKRPLKMEDPVCENEILATLHAISSKNQIWRSYIGMGY YNCSVPQTILRNLLENSGWITQYTPYQPEVSQGRLESLLNYQTMVC DITGLDMANASLLDEGTAAAEALQLCYRHNKRRKFLVDPRCHPQTI AVVQTRAKYTGVLTELKLPCEMDFSGKDVSGVLFQYPDTEGKVED FTELVERAHQSGSLACCATDLLALC ILRPPGEFGVDIALGSSQRFGVPLGYGGPHAAFFAVRESLVRMMPGR MVGVTRDATGKEVYRLALQTREQHIRRDKATSNICTAQALLANMA AMFAIYHGSHGLEHIARRVHNATLILSEGLKRAGHQLQHDLFFDTL KIQCGCSVKEVLGRAAQRQINFRLFEDGTLGISLDETVNEKDLDDLL WIFGCESSAELVAESMGEECRGIPGSVFKRTSPFLTHQVFNSYHSET NIVRYMKKLENKDISLVHSMIPLGSCTMKLNSSSELAPITWKEFANI HPFVPLDQAQGYQQLFRELEKDLCELTGYDQVCFQPNSGAQGEYA GLATIRAYLNQKGEGHRTVCLIPKSAHGTNPASAHMAGMKIQPVEV DKYGNIDAVHLKAMVDKHKENLAAIMITYPSTNGVFEENISDVCDL IHQHGGQVYLDGANMNAQVGICRPGDFGSDVSHLNLHKTFCIPHG GGGPGMGPIGVKKHLAPFLPNHPVISLKRNEDACPVGTVSAAPWGS SSILPISWAYIKMMGGKGLKQATETAILNANYMAKRLETHYRILFR GARGYVGHEFILDTRPFKKSANIEAVDVAKRLQDYGFHAPTMSWP VAGTLMVEPTESEDKAELDRFCDAMISIRQEIADIEEGRIDPRVNPLK MSPHSLTCVTSSHWDRPYSREVAAFPLPFVKPENKFWPTIARIDDIY GDQHLVCTCPPMEVYESPFSEQKRASS 330 MSLRCGDAARTLGPRVFGRYFCSPVRPLSSLPDKKKELLQNGPDLQ LIAS DFVSGDLADRSTWDEYKGNLKRQKGERLRLPPWLKTEIPMGKNYN KLKNTLRNLNLHTVCEEARCPNIGECWGGGEYATATATIMLMGDT CTRGCRFCSVKTARNPPPLDASEPYNTAKAIAEWGLDYVVLTSVDR DDMPDGGAEHIAKTVSYLKERNPKILVECLTPDFRGDLKAIEKVALS GLDVYAHNVETVPELQSKVRDPRANFDQSLRVLKHAKKVQPDVIS KTSIMLGLGENDEQVYATMKALREADVDCLTLGQYMQPTRRHLK VEEYITPEKFKYWEKVGNELGFHYTASGPLVRSSYKAGEFFL KNLVAKRKTKDL 331 MAATARRGWGAAAVAAGLRRRFCHMLKNPYTIKKQPLHQFVQRP NFU1 LFPLPAAFYHPVRYMFIQTQDTPNPNSLKFIPGKPVLETRTMDFPTPA AAFRSPLARQLFRIEGVKSVFFGPDFITVTKENEELDWNLLKPDIYAT IMDFFASGLPLVTEETPSGEAGSEEDDEVVAMIKELLDTRIRPTVQE DGGDVIYKGFEDGIVQLKLQGSCTSCPSSIITLKNGIQNMLQFYIPEV EGVEQVMDDESDEKEANSP 332 MSGGDTRAAIARPRMAAAHGPVAPSSPEQVTLLPVQRSFFLPPFSGA SLC6A9 TPSTSLAESVLKVWHGAYNSGLLPQLMAQHSLAMAQNGAVPSEAT KRDQNLKRGNWGNQIEFVLTSVGYAVGLGNVWRFPYLCYRNGGG AFMFPYFIMLIFCGIPLFFMELSFGQFASQGCLGVWRISPMFKGVGY GMMVVSTYIGIYYNVVICIAFYYFFSSMTHVLPWAYCNNPWNTHD CAGVLDASNLTNGSRPAALPSNLSHLLNHSLQRTSPSEEYWRLYVL KLSDDIGNFGEVRLPLLGCLGVSWLVVFLCLIRGVKSSGKVVYFTA TFPYVVLTILFVRGVTLEGAFDGIMYYLTPQWDKILEAKVWGDAAS QIFYSLGCAWGGLITMASYNKFHNNCYRDSVIISITNCATSVYAGFV IFSILGFMANHLGVDVSRVADHGPGLAFVAYPEALTLLPISPLWSLL FFFMLILLGLGTQFCLLETLVTAIVDEVGNEWILQKKTYVTLGVAVA GFLLGIPLTSQAGIYWLLLMDNYAASFSLVVISCIMCVAIMYIYGHR NYFQDIQMMLGFPPPLFFQICWRFVSPAIIFFILVFTVIQYQPITYNHY QYPGWAVAIGFLMALSSVLCIPLYAMFRLCRTDGDTLLQRLKNATK PSRDWGPALLEHRTGRYAPTIAPSPEDGFEVQPLHPDKAQIPIVGSN GSSRLQDSRI 333 MEPSSKKLTGRLMLAVGGAVLGSLQFGYNTGVINAPQKVIEEFYNQ SLC2A1 TWVHRYGESILPTTLTTLWSLSVAIFSVGGMIGSFSVGLFVNRFGRR NSMLMMNLLAFVSAVLMGFSKLGKSFEMLILGRFIIGVYCGLTTGF VPMYVGEVSPTALRGALGTLHQLGIVVGILIAQVFGLDSIMGNKDL WPLLLSIIFIPALLQCIVLPFCPESPRFLLINRNEENRAKSVLKKLRGT ADVTHDLQEMKEESRQMMREKKVTILELFRSPAYRQPILIAVVLQL SQQLSGINAVFYYSTSIFEKAGVQQPVYATIGSGIVNTAFTVVSLFVV ERAGRRTLHLIGLAGMAGCAILMTIALALLEQLPWMSYLSIVAIFGF VAFFEVGPGPIPWFIVAELFSQGPRPAAIAVAGFSNWTSNFIVGMCF QYVEQLCGPYVFIIFTVLLVLFFIFTYFKVPETKGRTFDEIASGFRQG GASQSDKTPE ELFHPLGADSQV 334 MDPSMGVNSVTISVEGMTCNSCVWTIEQQIGKVNGVHHIKVSLEEK ATP7A NATIIYDPKLQTPKTLQEAIDDMGFDAVIHNPDPLPVLTDTLFLTVTA SLTLPWDHIQSTLLKTKGVTDIKIYPQKRTVAVTIIPSIVNANQIKELV PELSLDTGTLEKKSGACEDHSMAQAGEVVLKMKVEGMTCHSCTST IEGKIGKLQGVQRIKVSLDNQEATIVYQPHLISVEEMKKQIEAMGFP AFVKKQPKYLKLGAIDVERLKNTPVKSSEGSQQRSPSYTNDSTATFII DGMHCKSCVSNIESTLSALQYVSSIVVSLENRSAIVKYNASSVTPESL RKAIEAVSPGLYRVSITSEVESTSNSPSSSSLQKIPLNVVSQPLTQETV INIDGMTCNSCVQSIEGVISKKPGVKSIRVSLANSNGTVEYDPLLTSP ETLRGAIEDMGFDATLSDTNEPLVVIAQPSSEMPLLTSTNEFYTKGM TPVQD KEEGKNSSKCYIQVTGMTCASCVANIERNLRREEGIYSILVALMAG KAEVRYNPAVIQPPMIAEFIRELGFGATVIENADEGDGVLELVVRG MTCASCVHKIESSLTKHRGILYCSVALATNKAHIKYDPEIIGPRDIIHT IESLGFEASLVKKDRSASHLDHKREIRQWRRSFLVSLFFCIPVMGLMI YMMVMDHHFATLHHNQNMSKEEMINLHSSMFLERQILPGLSVMNL LSFLLC VPVQFFGGWYFYIQAYKALKHKTANMDVLIVLATTIAFAYSLIILLV AMYERAKVNPITFFDTPPMLFVFIALGRWLEHIAKGKTSEALAKLIS LQATEATIVTLDSDNILLSEEQVDVELVQRGDIIKVVPGGKFPVDGR VIEGHSMVDESLITGEAMPVAKKPGSTVIAGSINQNGSLLICATHVG ADTTLSQIVKLVEEAQTSKAPIQQFADKLSGYFVPFIVFVSIATLLVW IVIG FLNFEIVETYFPGYNRSISRTETIIRFAFQASITVLCIACPCSLGLATPT AVMVGTGVGAQNGILIKGGEPLEMAHKVKVVVFDKTGTITHGTPV VNQVKVLTESNRISHHKILAIVGTAESNSEHPLGTAITKYCKQELDTE TLGTCIDFQVVPGCGISCKVTNIEGLLHKNNWNIEDNNIKNASLVQI DASNEQSSTSSSMIIDAQISNALNAQQYKVLIGNREWMIRNGLVINN DVN DFMTEHERKGRTAVLVAVDDELCGLIAIADTVKPEAELAIHILKSMG LEVVLMTGDNSKTARSIASQVGITKVFAEVLPSHKVAKVKQLQEEG KRVAMVGDGINDSPALAMANVGIAIGTGTDVAIEAADVVLIRNDLL DVVASIDLSRKTVKRIRINFVFALIYNLVGIPIAAGVFMPIGLVLQPW MGSAAMAASSVSVVLSSLFLKLYRKPTYESYELPARSQIGQKSPSEI SVHVGIDDTSRNSPKLGLLDRIVNYSRASINSLLSDKRSLNSVVTSEP DKHSLLVGDFREDDDTAL 335 MMRFMLLFSRQGKLRLQKWYLATSDKERKKMVRELMQVVLARKP AP1S1 KMCSFLEWRDLKVVYKRYASLYFCCAIEGQDNELITLELIHRYVEL LDKYFGSVCELDIIFNFEKAYFILDEFLMGGDVQDTSKKSVLKAIEQ ADLLQEEDESPRSVLEEMGLA 336 MKILILGIFLFLCSTPAWAKEKHYYIGIIETTWDYASDHGEKKLISVD CP TEHSNIYLQNGPDRIGRLYKKALYLQYTDETFRTTIEKPVWLGFLGPI IKAETGDKVYVHLKNLASRPYTFHSHGITYYKEHEGAIYPDNTTDF QRADDKVYPGEQYTYMLLATEEQSPGEGDGNCVTRIYHSHIDAPK DIASGLIGPLIICKKDSLDKEKEKHIDREFVVMFSVVDENFSWYLED NIKTYC SEPEKVDKDNEDFQESNRMYSVNGYTFGSLPGLSMCAEDRVKWYL FGMGNEVDVHAAFFHGQALTNKNYRIDTINLFPATLFDAYMVAQN PGEWMLSCQNLNHLKAGLQAFFQVQECNKSSSKDNIRGKHVRHYY IAAEEIIWNYAPSGIDIFTKENLTAPGSDSAVFFEQGTTRIGGSYKKL VYREYTDASFTNRKERGPEEEHLGILGPVIWAEVGDTIRVTFHNKG AYPLSIEPIGVRFNKNNEGTYYSPNYNPQSRSVPPSASHVAPTETFTY EWTVPKEVGPTNADPVCLAKMYY SAVDPTKDIFTGLIGPMKICKKGSLHANGRQKDVDKEFYLFPTVFDE NESLLLEDNIRMFTTAPDQVDKEDEDFQESNKMHSMNGFMYGNQP GLTMCKGDSVVWYLFSAGNEADVHGIYFSGNTYLWRGERRDTAN LFPQTSLTLHMWPDTEGTFNVECLTTDHYTGGMKQKYTVNQCRRQ SEDSTFYLGERTYYIAAVEVEWDYSPQREWEKELHHLQEQNVSNAF LDKGEFYIGSKYKKVVYRQYTDSTFRVPVERKAEEEHLGILGPQLH ADVGDKVKIIFKNMATRPYSIHAHGVQTESSTVTPTLPGETLTYVW KIPERSGAGTEDSACIPWAYYSTVDQVKDLYSGLIGPLIVCRRPYLK VFNPRRKLEFALLFLVFDENESWYLDDNIKTYSDHPEKVNKDDEEFI ESNKMHAINGRMFGNLQGLTMHVGDEVNWYLMGMGNEIDLHTV HFHGHSFQYKHRGVYSSDVFDIFPGTYQTLEMFPRTPGIWLLHCHV TDHIHAGMETTYTVLQNEDTKSG 337 MSPTISHKDSSRQRRPGNFSHSLDMKSGPLPPGGWDDSHLDSAGRE SLC33A1 GDREALLGDTGTGDFLKAPQSFRAELSSILLLLFLYVLQGIPLGLAGS IPLILQSKNVSYTDQAFFSFVFWPFSLKLLWAPLVDAVYVKNFGRRK SWLVPTQYILGLFMIYLSTQVDRLLGNTDDRTPDVIALTVAFFLFEF LAATQDIAVDGWALTMLSRENVGYASTCNSVGQTAGYFLGNVLFL ALESADFCNKYLRFQPQPRGIVTLSDFLFFWGTVFLITTTLVALLKK ENEVSVVKEETQGITDTYKL LFAIIKMPAVLTFCLLILTAKIGFSAADAVTGLKLVEEGVPKEHLALL AVPMVPLQIILPLIISKYTAGPQPLNTFYKAMPYRLLLGLEYALLVW WTPKVEHQGGFPIYYYIVVLLSYALHQVTVYSMYVSIMAFNAKVS DPLIGGTYMTLLNTVSNLGGNWPSTVALWLVDPLTVKECVGASNQ NCRTPDAVELCKKLGGSCVTALDGYYVESIICVFIGFGWWFFLGPKF KKLQDEGSSSWKCKRNN 338 MSAVCGGAARMLRTPGRHGYAAEFSPYLPGRLACATAQHYGIAGC PEX7 GTLLILDPDEAGLRLFRSFDWNDGLFDVTWSENNEHVLITCSGDGSL QLWDTAKAAGPLQVYKEHAQEVYSVDWSQTRGEQLVVSGSWDQT VKLWDPTVGKSLCTFRGHESIIYSTIWSPHIPGCFASASGDQTLRIWD VKAAGVRIVIPAHQAEILSCDWCKYNENLLVTGAVDCSLRGWDLR NVRQPVFELLGHTYAIRRVKFSPFHASVLASCSYDFTVRFWNFSKPD SLLETVEHHTEFTCGLDFSLQSPTQVADCSWDETIKIYDPACLTIPA 339 MEQLRAAARLQIVLGHLGRPSAGAVVAHPTSGTISSASFHPQQFQY PHYH TLDNNVLTLEQRKFYEENGFLVIKNLVPDADIQRFRNEFEKICRKEV KPLGLTVMRDVTISKSEYAPSEKMITKVQDFQEDKELFRYCTLPEIL KYVECFTGPNIMAMHTMLINKPPDSGKKTSRHPLHQDLHYFPFRPS DLIVCAWTAMEHISRNNGCLVVLPGTHKGSLKPHDYPKWEGGVNK MFHGIQDYEENKARVHLVMEKGDTVFFHPLLIHGSGQNKTQGFRK AISCHFASADCHYIDVKGTSQENIEKEVVGIAHKFFGAENSVNLKDI WMFRARLVKGERTNL 340 MAEAAAAAGGTGLGAGASYGSAADRDRDPDPDRAGRRLRVLSGH AGPS LLGRPREALSTNECKARRAASAATAAPTATPAAQESGTIPKKRQEV MKWNGWGYNDSKFIFNKKGQIELTGKRYPLSGMGLPTFKEWIQNT LGVNVEHKTTSKASLNPSDTPPSVVNEDFLHDLKETNISYSQEADDR VFRAHGHCLHEIFLLREGMFERIPDIVLWPTCHDDVVKIVNLACKY NLCIIPIGGGTSVSYGLMCPADETRTIISLDTSQMNRILWVDENNLTA HVEAGITGQELERQLKESGYCTGH EPDSLEFSTVGGWVSTRASGMKKNIYGNIEDLVVHIKMVTPRGIIEK SCQGPRMSTGPDIHHFIMGSEGTLGVITEATIKIRPVPEYQKYGSVAF PNFEQGVACLREIAKQRCAPASIRLMDNKQFQFGHALKPQVSSIFTS FLDGLKKFYITKFKGFDPNQLSVATLLFEGDREKVLQHEKQVYDIA AKFGGLAAGEDNGQRGYLLTYVIAYIRDLALEYYVLGESFETSAPW DRVVDLCRNVKERITRECKEKGVQFAPFSTCRVTQTYDAGACIYFY FAFNYRGISDPLTVFEQTEAAAREEILANGGSLSHHHGVGKLRKQW LKESISDVGFGMLKSVKEYVDPNNIFGNRNLL 341 MESSSSSNSYFSVGPTSPSAVVLLYSKELKKWDEFEDILEERRHVSD GNPAT LKFAMKCYTPLVYKGITPCKPIDIKCSVLNSEEIHYVIKQLSKESLQS VDVLREEVSEILDEMSHKLRLGAIRFCAFTLSKVFKQIFSKVCVNEE GIQKLQRAIQEHPVVLLPSHRSYIDFLMLSFLLYNYDLPVPVIAAGM DFLGMKMVGELLRMSGAFFMRRTFGGNKLYWAVFSEYVKTMLRN GYAPVEFFLEGTRSRSAKTLTPKFGLLNIVMEPFFKREVFDTYLVPIS ISYDKILEETLYVYELLGVPKPKESTTGLLKARKILSENFGSIHVYFG DPVSLRSLAAGRMSRSSYNLVPRYIPQKQSEDMHAFVTEVAYKMEL LQIENMVLSPWTLIVAVLLQNRPSMDFDALVEKTLWLKGLTQAFGG FLIWPDNKPAEEVVPASILLHSNIASLVKDQVILKVDSGDSEVVDGL MLQHITLLMCSAYRNQLLNIFVRPSLVAVALQMTPGFRKEDVYSCF RFLRDVFADEFIFLPGNTLKDFEEGCYLLCKSEAIQVTTKDILVTEKG NTVLEFLVGLFKPFVESYQIICKYLLSEEEDHFSEEQYLAAVRKFTSQ LLDQGTSQCYDVLSSDVQKNALAACVRLGVVEKKKINNNCIFNVN EPATTKLEEMLGCKTPIGKPATAKL 342 MPVLSRPRPWRGNTLKRTAVLLALAAYGAHKVYPLVRQCLAPARG ABCD1 LQAPAGEPTQEASGVAAAKAGMNRVFLQRLLWLLRLLFPRVLCRE TGLLALHSAALVSRTFLSVYVARLDGRLARCIVRKDPRAFGWQLLQ WLLIALPATFVNSAIRYLEGQLALSFRSRLVAHAYRLYFSQQTYYRV SNMDGRLRNPDQSLTEDVVAFAASVAHLYSNLTKPLLDVAVTSYT LLRAARSRGAGTAWPSAIAGLVVFLTANVLRAFSPKFGELVAEEAR RKGELRYMHSRVVANSEEIAFYGGHEVELALLQRSYQDLASQINLIL LERLWYVMLEQFLMKYVWSASGLLMVAVPIITATGYSESDAEAVK KAALEKKEEELVSERTEAFTIARNLLTAAADAIERIMSSYKEVTELA GYTARVHEMFQVFEDVQRCHFKRPRELEDAQAGSGTIGRSGVRVE GPLKIRGQVVDVEQGIICENIPIVTPSGEVVVASLNIRVEEGMHLLITG PNGCGKSSLFRILGGLWPTYGGVLYKPPPQRMFYIPQRPYMSVGSL RDQVIYPDSVEDMQRKGYSEQDLEAILDVVHLHHILQREGGWEAM CD WKDVLSGGEKQRIGMARMFYHRPKYALLDECTSAVSIDVEGKIFQ AAKDAGIALLSITHRPSLWKYHTHLLQFDGEGGWKFEKLDSAARLS LTEEKQRLEQQLAGIPKMQRRLQELCQILGEAVAPAHVPAPSPQGP GGLQGAST 343 MNPDLRRERDSASFNPELLTHILDGSPEKTRRRREIENMILNDPDFQ ACOX1 HEDLNFLTRSQRYEVAVRKSAIMVKKMREFGIADPDEIMWFKKLHL VNFVEPVGLNYSMFIPTLLNQGTTAQKEKWLLSSKGLQIIGTYAQTE MGHGTHLRGLETTATYDPETQEFILNSPTVTSIKWWPGGLGKTSNH AIVLAQLITKGKCYGLHAFIVPIREIGTHKPLPGITVGDIGPKFGYDEI DNGYLKMDNHRIPRENMLMKYAQVKPDGTYVKPLSNKLTYGTMV FVRSFLVGEAARALSKACTIAIRYSAVRHQSEIKPGEPEPQILDFQTQ QYKLFPLLATAYAFQFVGAYMKETYHRINEGIGQGDLSELPELHAL TAGLKAFTSWTANTGIEACRMACGGHGYSHCSGLPNIYVNFTPSCT FEGENTVMMLQTARFLMKSYDQVHSGKLVCGMVSYLNDLPSQRIQ PQQVAVWPTMVDINSPESLTEAYKLRAARLVEIAAKNLQKEVIHRK SKEVAWNLTSVDLVRASEAHCHYVVVKLFSEKLLKIQDKAIQAVLR SLCLLYSLYGISQNAGDFLQGSIMTEPQITQVNQRVKELLTLIRSDAV ALVDAFDFQDVTLGSVLGRYDGNVYENLFEWAKNSPLNKAEVHES YKHLKSLQSKL 344 MWGSDRLAGAGGGGAAVTVAFTNARDCFLHLPRRLVAQLHLLQN PEX1 QAIEVVWSHQPAFLSWVEGRHFSDQGENVAEINRQVGQKLGLSNG GQVFLKPCSHVVSCQQVEVEPLSADDWEILELHAVSLEQHLLDQIRI VFPKAIFPVWVDQQTYIFIQIVALIPAASYGRLETDTKLLIQPKTRRA KENTFSKADAEYKKLHSYGRDQKGMMKELQTKQLQSNTVGITESN ENESEIPVDSSSVASLWTMIGSIFSFQSEKKQETSWGLTEINAFKNMQ SKVVPLDNIFRVCKSQPPSIYNASATSVFHKHCAIHVFPWDQEYFDV EPSFTVTYGKLVKLLSPKQQQSKTKQNVLSPEKEKQMSEPLDQKKI RSDHNEEDEKACVLQVVWNGLEELNNAIKYTKNVEVLHLGKVWIP DDLRKRLNIEMHAVVRITPVEVTPKIPRSLKLQPRENLPKDISEEDIK TVFYSWLQQSTTTMLPLVISEEEFIKLETKDGLKEFSLSIVHSWEKEK DKNIFLLSPNLLQKTTIQVLLDPMVKEEN SEEIDFILPFLKLSSLGGVNSLGVSSLEHITHSLLGRPLSRQLMSLVAG LRNGALLLTGGKGSGKSTLAKAICKEAFDKLDAHVERVDCKALRG KRLENIQKTLEVAFSEAVWMQPSVVLLDDLDLIAGLPAVPEHEHSP DAVQSQRLAHALNDMIKEFISMGSLVALIATSQSQQSLHPLLVSAQG VHIFQCVQHIQPPNQEQRCEILCNVIKNKLDCDINKFTDLDLQHVAK ETGGFVARDFTVLVDRAIHSRLSRQSISTREKLVLTTLDFQKALRGF LPASLRSVNLHKPRDLGWDKIGGLHEVRQILMDTIQLPAKYPELFA NLPIRQRTGILLYGPPGTGKTLLAGVIARESRMNFISVKGPELLSKYI GASEQAVRDIFIRAQAAKPCILFFDEFESIAPRRGHDNTGVTDRVVN QLLTQLDGVEGLQGVYVLAATSRPDLIDPALLRPGRLDKCVYCPPP DQVSRLEILNVLSDSLPLADDVDLQHVASVTDSFTGADLKALLYNA QLEALHGMLLSSGLQDGSSSSDSDLSLSSMVFLNHSSGSDDSAGDG ECGLDQSLVSLEMSEILPDESKFNMYRLYFGSSYESELGNGTSSDLS SQCLSAPSSMTQDLPGVPGKDQLFSQPPVLRTASQEGCQELTQEQR DQLRADISIIKGRYRSQSGEDESMNQPGPIKTRLAISQSHLMTALGHT RPSISEDDWKNFAELYESFQNPKRRKNQSGTMFRPGQKVTLA 345 MASRKENAKSANRVLRISQLDALELNKALEQLVWSQFTQCFHGFKP PEX2 GLLARFEPEVKACLWVFLWRFTIYSKNATVGQSVLNIKYKNDFSPN LRYQPPSKNQKIWYAVCTIGGRWLEERCYDLFRNHHLASFGKVKQ CVNFVIGLLKLGGLINFLIFLQRGKFATLTERLLGIHSVFCKPQNICEV GFEYMNRELLWHGFAEFLIFLLPLINVQKLKAKLSSWCIPLTGAPNS DNTLATSGKECALCGEWPTMPHTIGCEHIFCYFCAKSSFLFDVYFTC PKCGTEVHSLQPLKSGIEMSEVNAL 346 MLRSVWNFLKRHKKKCIFLGTVLGGVYILGKYGQKKIREIQEREAA PEX3 EYIAQARRQYHFESNQRTCNMTVLSMLPTLREALMQQLNSESLTAL LKNRPSNKLEIWEDLKIISFTRSTVAVYSTCMLVVLLRVQLNIIGGYI YLDNAAVGKNGTTILAPPDVQQQYLSSIQHLLGDGLTELITVIKQAV QKVLGSVSLKHSLSLLDLEQKLKEIRNLVEQHKSSSWINKDGSKPLL CHYMMPDEETPLAVQACGLSPRDITTIKLLNETRDMLESPDFSTVLN TCLNRGFSRLLDNMAEFFRPTEQDLQHGNSMNSLSSVSLPLAKIIPIV NGQIHSVCSETPSHFVQDLLTMEQVKDFAANVYEAFSTPQQLEK 347 MAMRELVEAECGGANPLMKLAGHFTQDKALRQEGLRPGPWPPGA PEX5 PASEAASKPLGVASEDELVAEFLQDQNAPLVSRAPQTFKMDDLLAE MQQIEQSNFRQAPQRAPGVADLALSENWAQEFLAAGDAVDVTQD YNETDWSQEFISEVTDPLSVSPARWAEEYLEQSEEKLWLGEPEGTA TDRWYDEYHPEEDLQHTASDFVAKVDDPKLANSEFLKFVRQIGEG QVSLESGAGSGRAQAEQWAAEFIQQQGTSDAWVDQFTRPVNTSAL DMEFERAKSAIESDVDFWDKLQAELEEMAKRDAEAHPWLSDYDDL TSATYDKGYQFEEENPLRDHPQPFEEGLRRLQEGDLPNAVLLFEAA VQQDPKHMEAWQYLGTTQAENEQELLAISALRRCLELKPDNQTAL MALAVSFTNESLQRQACETLRDWLRYTPAYAHLVTPAEEGAGGAG LGPSKRILGSLLSDSLFLEVKELFLAAVRLDPTSIDPDVQCGLGVLFN LSGEYDKAVDCFTAALSVRPNDYLLWNKLGATLANGNQSEEAVAA YRRALELQPGYIRSRYNLGISCINLGAHREAVEHFLEALNMQRKSRG PRGEGGAMSENIWSTLRLALSMLGQSDAYGAADARDLSTLLTMFG LPQ 348 MALAVLRVLEPFPTETPPLAVLLPPGGPWPAAELGLVLALRPAGESP PEX6 AGPALLVAALEGPDAGTEEQGPGPPQLLVSRALLRLLALGSGAWVR ARAVRRPPALGWALLGTSLGPGLGPRVGPLLVRRGETLPVPGPRVL ETRPALQGLLGPGTRLAVTELRGRARLCPESGDSSRPPPPPVVSSFA VSGTVRRLQGVLGGTGDSLGVSRSCLRGLGLFQGEWVWVAQARES SNTSQPHLARVQVLEPRWDLSDRLGPGSGPLGEPLADGLALVPATL AFNLGCDPLEMGELRIQRYLEGS IAPEDKGSCSLLPGPPFARELHIEIVSSPHYSTNGNYDGVLYRHFQIPR VVQEGDVLCVPTIGQVEILEGSPEKLPRWREMFFKVKKTVGEAPDG PASAYLADTTHTSLYMVGSTLSPVPWLPSEESTLWSSLSPPGLEALV SELCAVLKPRLQPGGALLTGTSSVLLRGPPGCGKTTVVAAACSHLG LHLLKVPCSSLCAESSGAVETKLQAIFSRARRCRPAVLLLTAVDLLG RDRDGLGEDARVMAVLRHLLLNEDPLNSCPPLMVVATTSRAQDLP ADVQTAFPHELEVPALSEGQRLSILRALTAHLPLGQEVNLAQLARR CAGFVVGDLYALLTHSSRAACTRIKNSGLAGGLTEEDEGELCAAGF PLLAEDFGQALEQLQTAHSQAVGAPKIPSVSWHDVGGLQEVKKEIL ETIQLPLEHPELLSLGLRRSGLLLHGPPGTGKTLLAKAVATECSLTFL SVKGPELINMYVGQSEENVREVFARARAAAPCIIFFDELDSLAPSRG RSGDSGGVMDRVVSQLLAELDGLHSTQ DVFVIGATNRPDLLDPALLRPGRFDKLVFVGANEDRASQLRVLSAIT RKFKLEPSVSLVNVLDCCPPQLTGADLYSLCSDAMTAALKRRVHDL EEGLEPGSSALMLTMEDLLQAAARLQPSVSEQELLRYKRIQRKFAA C 349 MAPAAASPPEVIRAAQKDEYYRGGLRSAAGGALHSLAGARKWLE PEX10 WRKEVELLSDVAYFGLTTLAGYQTLGEEYVSIIQVDPSRIHVPSSLR RGVLVTLHAVLPYLLDKALLPLEQELQADPDSGRPLQGSLGPGGRG CSGARRWMRHHTATLTEQQRRALLRAVFVLRQGLACLQRLHVAW FYIHGVFYHLAKRLTGITYLRVRSLPGEDLRARVSYRLLGVISLLHL VLSMGLQLYGFRQRQRARKEWRLHRGLSHRRASLEERAVSRNPLC TLCLEERRHPTATPCGHLFCWECITAW CSSKAECPLCREKFPPQKLIYLRHYR 350 MAEHGAHFTAASVADDQPSIFEVVAQDSLMTAVRPALQHVVKVLA PEX12 ESNPTHYGFLWRWFDEIFTLLDLLLQQHYLSRTSASFSENFYGLKRI VMGDTHKSQRLASAGLPKQQLWKSIMFLVLLPYLKVKLEKLVSSL REEDEYSIHPPSSRWKRFYRAFLAAYPFVNMAWEGWFLVQQLRYIL GKAQHHSPLLRLAGVQLGRLTVQDIQALEHKPAKASMMQQPARSV SEKINSALKKAVGGVALSLSTGLSVGVFFLQFLDWWYSSENQETIKS LTALPTPPPPVHLDYNSDSPLLPKMKTVCPLCRKTRVNDTVLATSG YVFCYRCVFHYVRSHQACPITGYPTEVQHLIKLYSPEN 351 MASQPPPPPKPWETRRIPGAGPGPGPGPTFQSADLGPTLMTRPGQPA PEX13 LTRVPPPILPRPSQQTGSSSVNTFRPAYSSFSSGYGAYGNSFYGGYSP YSYGYNGLGYNRLRVDDLPPSRFVQQAEESSRGAFQSIESIVHAFAS VSMMMDATFSAVYNSFRAVLDVANHFSRLKIHFTKVFSAFALVRTI RYLYRRLQRMLGLRRGSENEDLWAESEGTVACLGAEDRAATSAKS WPIFLFFAVILGGPYLIWKLLSTHSDEVTDSINWASGEDDHVVARAE YDFAAVSEEEISFRAGDMLNLALKEQQPKVRGWLLASLDGQTTGLI PANYVKILGKRKGRKTVESSKVSKQQQSFTNPTLTKGATVADSLDE QEAAFESVFVETNKVPVAPDSIGKDGEKQDL 352 MASSEQAEQPSQPSSTPGSENVLPREPLIATAVKFLQNSRVRQSPLAT PEX14 RRAFLKKKGLTDEEIDMAFQQSGTAADEPSSLGPATQVVPVQPPHLI SQPYSPAGSRWRDYGALAIIMAGIAFGFHQLYKKYLLPLILGGREDR KQLERMEAGLSELSGSVAQTVTQLQTTLASVQELLIQQQQKIQELA HELAAAKATTSTNWILESQNINELKSEINSLKGLLLNRRQFPPSPSAP KIPSWQIPVKSPSPSSPAAVNHHSSSDISPVSNESTSSSPGKEGHSPEG STVTYHLLGPQEEGEGVVDVKGQVRMEVQGEEEKREDKEDEEDEE DDDVSHVDEEDCLGVQREDRRGGDGQINEQVEKLRRPEGASNESE RD 353 MEKLRLLGLRYQEYVTRHPAATAQLETAVRGFSYLLAGRFADSHE PEX16 LSELVYSASNLLVLLNDGILRKELRKKLPVSLSQQKLLTWLSVLECV EVFMEMGAAKVWGEVGRWLVIALVQLAKAVLRMLLLLWFKAGL QTSPPIVPLDRETQAQPPDGDHSPGNHEQSYVGKRSNRVVRTLQNT PSLHSRHWGAPQQREGRQQQHHEELSATPTPLGLQETIAEFLYIARP LLHLLSLGLWGQRSWKPWLLAGVVDVTSLSLLSDRKGLTRRERRE LRRRTILLLYYLLRSPFYDRFSEARIL FLLQLLADHVPGVGLVTRPLMDYLPTWQKIYFYSWG 354 MAAAEEGCSVGAEADRELEELLESALDDFDKAKPSPAPPSTTTAPD PEX19 ASGPQKRSPGDTAKDALFASQEKFFQELFDSELASQATAEFEKAMK ELAEEEPHLVEQFQKLSEAAGRVGSDMTSQQEFTSCLKETLSGLAK NATDLQNSSMSEEELTKAMEGLGMDEGDGEGNILPIMQSIMQNLLS KDVLYPSLKEITEKYPEWLQSHRESLPPEQFEKYQEQHSVMCKICEQ FEAETPTDSETTQKARFEMVLDLMQQLQDLGHPPKELAGEMPPGLN FDLDALNLSGPPGASGEQCLIM 355 MKSDSSTSAAPLRGLGGPLRSSEPVRAVPARAPAVDLLEEAADLLV PEX26 VHLDFRAALETCERAWQSLANHAVAEEPAGTSLEVKCSLCVVGIQ ALAEMDRWQEVLSWVLQYYQVPEKLPPKVLELCILLYSKMQEPGA VLDVVGAWLQDPANQNLPEYGALAEFHVQRVLLPLGCLSEAEELV VGSAAFGEERRLDVLQAIHTARQQQKQEHSGSEEAQKPNLEGSVSH KFLSLPMLVRQLWDSAVSHFFSLPFKKSLLAALILCLLVVRFDPASP SSLHFLYKLAQLFRWIRKAAFSRLYQ LRIRD 356 MALQGISVVELSGLAPGPFCAMVLADFGARVVRVDRPGSRYDVSR AMACR LGRGKRSLVLDLKQPRGAAVLRRLCKRSDVLLEPFRRGVMEKLQL GPEILQRENPRLIYARLSGFGQSGSFCRLAGHDINYLALSGVLSKIGR SGENPYAPLNLLADFAGGGLMCALGIIMALFDRTRTGKGQVIDANM VEGTAYLSSFLWKTQKLSLWEAPRGQNMLDGGAPFYTTYRTADGE FMAVGAIEPQFYELLIKGLGLKSDELPNQMSMDDWPEMKKKFADV FAEKTKAEWCQIFDGTDACVTPVLTFEEVVHHDHNKERGSFITSEE QDVSPRPAPLLLNTPAIPSFKRDPFIGEHTEEILEEFGFSREEIYQLNSD KIIESNKVKASL 357 MAQTPAFDKPKVELHVHLDGSIKPETILYYGRRRGIALPANTAEGLL ADA NVIGMDKPLTLPDFLAKFDYYMPAIAGCREAIKRIAYEFVEMKAKE GVVYVEVRYSPHLLANSKVEPIPWNQAEGDLTPDEVVALVGQGLQ EGERDFGVKARSILCCMRHQPNWSPKVVELCKKYQQQTVVAIDLA GDETIPGSSLLPGHVQAYQEAVKSGIHRTVHAGEVGSAEVVKEAVD ILKTERLGHGYHTLEDQALYNRLRQENMHFEICPWSSYLTGAWKPD TEHAVIRLKNDQANYSLNTDDPLIF KSTLDTDYQMTKRDMGFTEEEFKRLNINAAKSSFLPEDEKRELLDL LYKAYGMPPSASAGQNL 358 MAAGGDHGSPDSYRSPLASRYASPEMCFVFSDRYKFRTWRQLWL ADSL WLAEAEQTLGLPITDEQIQEMKSNLENIDFKMAAEEEKRLRHDVMA HVHTFGHCCPKAAGIIHLGATSCYVGDNTDLIILRNALDLLLPKLAR VISRLADFAKERASLPTLGFTHFQPAQLTTVGKRCCLWIQDLCMDL QNLKRVRDDLRFRGVKGTTGTQASFLQLFEGDDHKVEQLDKMVTE KAGFKRAFIITGQTYTRKVDIEVLSVLASLGASVHKICTDIRLLANLK EMEEPFEKQQIGSSAMPYKRNPMRSERCCSLARHLMTLVMDPLQT ASVQWFERTLDDSANRRICLAEAFLTADTILNTLQNISEGLVVYPKV IERRIRQELPFMATENIIMAMVKAGGSRQDCHEKIRVLSQQAASVVK QEGGDNDLIERIQVDAYFSPIHSQLDHLLDPSSFTGRASQQVQRFLEE EVYPLLKPYESVMKVKAELCL 359 MNVRIFYSVSQSPHSLLSLLFYCAILESRISATMPLFKLPAEEKQIDD AMPD1 AMRNFAEKVFASEVKDEGGRQEISPFDVDEICPISHHEMQAHIFHLE TLSTSTEARRKKRFQGRKTVNLSIPLSETSSTKLSHIDEYISSSPTYQT VPDFQRVQITGDYASGVTVEDFEIVCKGLYRALCIREKYMQKSFQR FPKTPSKYLRNIDGEAWVANESFYPVFTPPVKKGEDPFRTDNLPENL GYHLKMKDGVVYVYPNEAAVSKDEPKPLPYPNLDTFLDDMNFLLA LIAQGPVKTYTHRRLKFLSSKFQVHQMLNEMDELKELKNNPHRDF YNCRKVDTHIHAAACMNQKHLLRFIKKSYQIDADRVVYSTKEKNL TLKELFAKLKMHPYDLTVDSLDVHAGRQTFQRFDKFNDKYNPVGA SELRDLYLKTDNYINGEYFATIIKEVGADLVEAKYQHAEPRLSIYGR SPDEWSKLSSWFVCNRIHCPNMTWMIQVPRIYDVFRSKNFLPHFGK MLENIFMPVFEATINPQADPELSVFLKHIT GFDSVDDESKHSGHMFSSKSPKPQEWTLEKNPSYTYYAYYMYANI MVLNSLRKERGMNTFLFRPHCGEAGALTHLMTAFMIADDISHGLNL KKSPVLQYLFFLAQIPIAMSPLSNNSLFLEYAKNPFLDFLQKGLMISL STDDPMQFHFTKEPLMEEYAIAAQVFKLSTCDMCEVARNSVLQCGI SHEEKVKFLGDNYLEEGPAGNDIRRTNVAQIRMAYRYETWCYELN LIAEGLKSTE 360 MATEGMILTNHDHQIRVGVLTVSDSCFRNLAEDRSGINLKDLVQDP GPHN SLLGGTISAYKIVPDEIEEIKETLIDWCDEKELNLILTTGGTGFAPRDV TPEATKEVIEREAPGMALAMLMGSLNVTPLGMLSRPVCGIRGKTLII NLPGSKKGSQECFQFILPALPHAIDLLRDAIVKVKEVHDELEDLPSPP PPLSPPPTTSPHKQTEDKGVQCEEEEEEKKDSGVASTEDSSSSHITAA AIAAKIPDSIISRGVQVLPRDTASLSTTPSESPRAQATSRLSTASCPTP KVQSRCSSKENILRASHSAVDITKVARRHRMSPFPLTSMDKAFITVL EMTPVLGTEIINYRDGMGRVLAQDVYAKDNLPPFPASVKDGYAVR AADGPGDRFIIGESQAGEQPTQTVMPGQVMRVTTGAPIPCGADAVV QVEDTELIRESDDGTEELEVRILVQARPGQDIRPIGHDIKRGECVLAK GTHMGPS EIGLLATVGVTEVEVNKFPVVAVMSTGNELLNPEDDLLPGKIRDSN RSTLLATIQEHGYPTINLGIVGDNPDDLLNALNEGISRADVIITSGGVS MGEKDYLKQVLDIDLHAQIHFGRVFMKPGLPTTFATLDIDGVRKIIF ALPGNPVSAVVTCNLFVVPALRKMQGILDPRPTIIKARLSCDVKLDP RPEYHRCILTWHHQEPLPWAQSTGNQMSSRLMSMRSANGLLMLPP KTEQYVELHKGEVVDVMVIGRL 361 MAGAAAESGRELWTFAGSRDPSAPRLAYGYGPGSLRELRAREFSRL MOCOS AGTVYLDHAGATLFSQSQLESFTSDLMENTYGNPHSQNISSKLTHD TVEQVRYRILAHFHTTAEDYTVIFTAGSTAALKLVAEAFPWVSQGP ESSGSRFCYLTDSHTSVVGMRNVTMAINVISTPVRPEDLWSAEERSA SASNPDCQLPHLFCYPAQSNFSGVRYPLSWIEEVKSGRLHPVSTPGK WFVLLDAASYVSTSPLDLSAHQADFVPISFYKIFGFPTGLGALLVHN RAAPLLRKTYFGGGTASAYLAGEDFYIPRQSVAQRFEDGTISFLDVI ALKHGFDTLERLTGGMENIKQHTFTLAQYTYVALSSLQYPNGAPVV RIYSDSEFSSPEVQGPIINFNVLDDKGNIIGYSQVDKMASLYNIHLRT GCFCNTGACQRHLGISNEMVRKHFQAGHVCGDNMDLIDGQPTGSV RISFGYMSTLDDVQAFLRFIIDTRLHSSGDWPVPQAHADTGETGAPS ADSQADVIPAVMGRRSLSPQEDALTGSRVWNNSSTVNAVPVAPPV CDVARTQPTPSEKAAGVLEGALGPHVVTNLYLYPIKSCAAFEVTRW PVGNQGLLYDRSWMVVNHNGVCLSQKQEPRLCLIQPFIDLRQRIMV IKAKGMEPIEVPLEENSERTQIRQSRVCADRVSTYDCGEKISSWLSTF FGRPCHLIKQSSNSQRNAKKKHGKDQLPGTMATLSLVNEAQYLLIN TSSILELHRQLNTSDENGKEELFSLKDLSLRFRANIIINGKRAFEEEK WDEISIGSLRFQVLGPCHRCQMICIDQQTGQRNQHVFQKLSESRETK VNFGMYLMHASLDLSSPCFLSVGSQVLPVLKENVEGHDLPASEKHQ DVTS 362 MAARPLSRMLRRLLRSSARSCSSGAPVTQPCPGESARAASEEVSRRR MOCS1 QFLREHAAPFSAFLTDSFGRQHSYLRISLTEKCNLRCQYCMPEEGVP LTPKANLLTTEEILTLARLFVKEGIDKIRLTGGEPLIRPDVVDIVAQLQ RLEGLRTIGVTTNGINLARLLPQLQKAGLSAINISLDTLVPAKFEFIVR RKGFHKVMEGIHKAIELGYNPVKVNCVVMRGLNEDELLDFAALTE GLP LDVRFIEYMPFDGNKWNFKKMVSYKEMLDTVRQQWPELEKVPEEE SSTAKAFKIPGFQGQISFITSMSEHFCGTCNRLRITADGNLKVCLFGN SEVSLRDHLRAGASEQELLRIIGAAVGRKKRQHAGMFSISQMKNRP MILIELFLMFPNSPPANPSIFSWDPLHVQGLRPRMSFSSQVATLWKG CRVPQTPPLAQQRLGSGSFQRHYTSRADSDANSKCLSPGSWASAAP SGPQLTSEQLTHVDSEGRAAMVDVGRKPDTERVAVASAVVLLGPV AFKLVQQNQLKKGDALVVAQLAG VQAAKVTSQLIPLCHHVALSHIQVQLELDSTRHAVKIQASCRARGPT GVEMEALTSAAVAALTLYDMCKAVSRDIVLEEIKLISKTGGQRGDF HRA 363 MENGYTYEDYKNTAEWLLSHTKHRPQVAIICGSGLGGLTDKLTQA PNP QIFDYGEIPNFPRSTVPGHAGRLVFGFLNGRACVMMQGRFHMYEG YPLWKVTFPVRVFHLLGVDTLVVTNAAGGLNPKFEVGDIMLIRDHI NLPGFSGQNPLRGPNDERFGDRFPAMSDAYDRTMRQRALSTWKQM GEQRELQEGTYVMVAGPSFETVAECRVLQKLGADAVGMSTVPEVI VARHCGLRVFGFSLITNKVIMDYESLEKANHEEVLAAGKQAAQKLE QFVSILMASIPLPDKAS 364 MTADKLVFFVNGRKVVEKNADPETTLLAYLRRKLGLSGTKLGCGE XDH GGCGACTVMLSKYDRLQNKIVHFSANACLAPICSLHHVAVTTVEGI GSTKTRLHPVQERIAKSHGSQCGFCTPGIVMSMYTLLRNQPEPTMEE IENAFQGNLCRCTGYRPILQGFRTFARDGGCCGGDGNNPNCCMNQ KKDHSVSLSPSLFKPEEFTPLDPTQEPIFPPELLRLKDTPRKQLRFEGE RVTWIQASTLKELLDLKAQHPDAKLVVGNTEIGIEMKFKNMLFPMI VCPAWIPELNSVEHGPDGISFGAACPLSIVEKTLVDAVAKLPAQKTE VFRGVLEQLRWFAGKQVKSVASVGGNIITASPISDLNPVFMASGAK LTLVSRGTRRTVQMDHTFFPGYRKTLLSPEEILLSIEIPYSREGEYFSA FKQASRREDDIAKVTSGMRVLFKPGTTEVQELALCYGGMANRTISA LKTTQRQLSKLWKEELLQDVCAGLAEELHLPPDAPGGMVDFRCTL TLSFFFKFYLTVLQKLGQENLEDKCGKLDPTFASATLLFQKDPPADV QLFQEVPKGQSEEDMVGRPLPHLAADMQASGEAVYCDDIPRYENE LSLRLVTSTRAHAKIKSIDTSEAKKVPGFVCFISADDVPGSNITGICN DETVFAKDKVTCVGHIIGAVVADTPEHTQRAAQGVKITYEELPAIITI EDAIKNNSFYGPELKIEKGDLKKGFSEADNVVSGEIYIGGQEHFYLE THCTIAVPKGEAGEMELFVSTQNTMKTQSFVAKMLGVPANRIVVR VKRMGGGFGGKETRSTVVSTAVALAAYKTGRPVRCMLDRDEDML ITGGR HPFLARYKVGFMKTGTVVALEVDHFSNVGNTQDLSQSIMERALFH MDNCYKIPNIRGTGRLCKTNLPSNTAFRGFGGPQGMLIAECWMSEV AVTCGMPAEEVRRKNLYKEGDLTHFNQKLEGFTLPRCWEECLASS QYHARKSEVDKFNKENCWKKRGLCIIPTKFGISFTVPFLNQAGALLH VYTDGSVLLTHGGTEMGQGLHTKMVQVASRALKIPTSKIYISETST NTVPNTSPTAASVSADLNGQAVYAACQTILKRLEPYKKKNPSGSWE DWVTAAYMDTVSLSATGFYRTPNLGYSFETNSGNPFHYFSYGVAC SEVEIDCLTGDHKNLRTDIVMDVGSSLNPAIDIGQVEGAFVQGLGLF TLEELHYSPEGSLHTRGPSTYKIPAFGSIPIEFRVSLLRDCPNKKAIYA SKAVGEPPLFLAASIFFAIKDAIRAARAQHTGNNVKELFRLDSPATPE KIRNACVDKFTTLCVTGVPENCKPWSVRV 365 MLLLHRAVVLRLQQACRLKSIPSRICIQACSTNDSFQPQRPSLTFSGD SUOX NSSTQGWRVMGTLLGLGAVLAYQDHRCRAAQESTHIYTKEEVSSH TSPETGIWVTLGSEVFDVTEFVDLHPGGPSKLMLAAGGPLEPFWAL YAVHNQSHVRELLAQYKIGELNPEDKVAPTVETSDPYADDPVRHPA LKVNSQRPFNAEPPPELLTENYITPNPIFFTRNHLPVPNLDPDTYRLH VVGAPGGQSLSLSLDDLHNFPRYEITVTLQCAGNRRSEMTQVKEVK GLEWRTGAISTARWAGARLCDVLAQAGHQLCETEAHVCFEGLDSD PTGTAYGASIPLARAMDPEAEVLLAYEMNGQPLPRDHGFPVRVVVP GVVGARHVKWLGRVSVQPEESYSHWQRRDYKGFSPSVDWETVDF DSAPSIQELPVQSAITEPRDGETVESGEVTIKGYAWSGGGRAVIRVD VSLDGGLTWQVAKLDGEEQRPRKAWAWRLWQLKAPVPAGQKEL NIVCKAVDDGYNVQPDTVAPIWNLRGVLSNAWHRVHVYVSP 366 MFHLRTCAAKLRPLTASQTVKTFSQNRPAAARTFQQIRCYSAPVAA OGDH EPFLSGTSSNYVEEMYCAWLENPKSVHKSWDIFFRNTNAGAPPGTA YQSPLPLSRGSLAAVAHAQSLVEAQPNVDKLVEDHLAVQSLIRAYQ IRGHHVAQLDPLGILDADLDSSVPADIISSTDKLGFYGLDESDLDKVF HLPTTTFIGGQESALPLREIIRRLEMAYCQHIGVEFMFINDLEQCQWI RQKFETPGIMQFTNEEKRTLLARLVRSTRFEEFLQRKWSSEKRFGLE GCEVLIPALKTIIDKSSENGVDYVIMGMPHRGRLNVLANVIRKELEQ IFCQFDSKLEAADEGSGDVKYHLGMYHRRINRVTDRNITLSLVANP SHLEAADPVVMGKTKAEQFYCGDTEGKKVMSILLHGDAAFAGQGI VYETFHLSDLPSYTTHGTVHVVVNNQIGFTTDPRMARSSPYPTDVA RVVNAPIFHVNSDDPEAVMYVCKVAAEWRSTFHKDVVVDLVCYR RNGHNEMDEPMFTQPLMYKQIRKQKPVLQKYAELLVSQGVVNQPE YEEEISKYDKICEEAFARSKDEKILHIKHWLDSPWPGFFTLDGQPRS MSCPSTGLTEDILTHIGNVASSVPVENFTIHGGLSRILKTRGEMVKNR TVDWALAEYMAFGSLLKEGIHIRLSGQDVERGTFSHRHHVLHDQN VDKRTCIPMNHLWPNQAPYTVCNSSLSEYGVLGFELGFAMASPNAL VLWEAQFGDFHNTAQCIIDQFICPGQAKWVRQNGIVLLLPHGMEG MGPEHSSARPERFLQMCNDDPDVLPDLKEANFDINQLYDCNWVVV NCSTPGNFFHVLRRQILLPFRKPLIIFTPKSLLRHPEARSSFDEMLPGT HFQRVIPEDGPAAQNPENVKRLLFCTGKVYYDLTRERKARDMVGQ VAITRIEQLSPFPFDLLLKEVQKYPNAELAWCQEEHKNQGYYDYVK PRLRTTISRAKPVWYAGRDPAAAPATGNKKTHLTELQRLLDTAFDL DVFKNFS 367 MVGYDPKPDGRNNTKFQVAVAGSVSGLVTRALISPFDVIKIRFQLQ SLC25A19 HERLSRSDPSAKYHGILQASRQILQEEGPTAFWKGHVPAQILSIGYG AVQFLSFEMLTELVHRGSVYDAREFSVHFVCGGLAACMATLTVHP VDVLRTRFAAQGEPKVYNTLRHAVGTMYRSEGPQVFYKGLAPTLI AIFPYAGLQFSCYSSLKHLYKWAIPAEGKKNENLQNLLCGSGAGVIS KTLTYPLDLFKKRLQVGGFEHARAAFGQVRRYKGLMDCAKQVLQ KEGALGFFKGLSPSLLKAALSTGFMF FSYEFFCNVFHCMNRTASQR 368 MASATAAAARRGLGRALPLFWRGYQTERGVYGYRPRKPESREPQG DHTKD1 ALERPPVDHGLARLVTVYCEHGHKAAKINPLFTGQALLENVPEIQA LVQTLQGPFHTAGLLNMGKEEASLEEVLVYLNQIYCGQISIETSQLQ SQDEKDWFAKRFEELQKETFTTEERKHLSKLMLESQEFDHFLATKF STVKRYGGEGAESMMGFFHELLKMSAYSGITDVIIGMPHRGRLNLL TGLLQFPPELMFRKMRGLSEFPENFSATGDVLSHLTSSVDLYFGAHH PLHVTMLPNPSHLEAVNPVAVGK TRGRQQSRQDGDYSPDNSAQPGDRVICLQVHGDASFCGQGIVPETF TLSNLPHFRIGGSVHLIVNNQLGYTTPAERGRSSLYCSDIGKLVGCAI IHVNGDSPEEVVRATRLAFEYQRQFRKDVIIDLLCYRQWGHNELDE PFYTNPIMYKIIRARKSIPDTYAEHLIAGGLMTQEEVSEIKSSYYAKL NDHLNNMAHYRPPALNLQAHWQGLAQPEAQITTWSTGVPLDLLRF VGMKSVEVPRELQMHSHLLKTHVQSRMEKMMDGIKLDWATAEAL ALGSLLAQGFNVRLSGQDVGRGT FSQRHAIVVCQETDDTYIPLNHMDPNQKGFLEVSNSPLSEEAVLGFE YGMSIESPKLLPLWEAQFGDFFNGAQIIFDTFISGGEAKWLLQSGIVI LLPHGYDGAGPDHSSCRIERFLQMCDSAEEGVDGDTVNMFVVHPT TPAQYFHLLRRQMVRNFRKPLIVASPKMLLRLPAAVSTLQEMAPGT TFNPVIGDSSVDPKKVKTLVFCSGKHFYSLVKQRESLGAKKHDFAII RVEELCPFPLDSLQQEMSKYKHVKDHIWSQEEPQNMGPWSFVSPRF EKQLACKLRLVGRPPLPVPAV GIGTVHLHQHEDILAKTFA 369 MASALSYVSKFKSFVILFVTPLLLLPLVILMPAKFVRCAYVIILMAIY SLC13A5 WCTEVIPLAVTSLMPVLLFPLFQILDSRQVCVQYMKDTNMLFLGGLI VAVAVERWNLHKRIALRTLLWVGAKPARLMLGFMGVTALLSMWI SNTATTAMMVPIVEAILQQMEATSAATEAGLELVDKGKAKELPGSQ VIFEGPTLGQQEDQERKRLCKAMTLCICYAASIGGTATLTGTGPNVV LLGQMNELFPDSKDLVNFASWFAFAFPNMLVMLLFAWLWLQFVY MRFNFKKSWGCGLESKKNEKAALKVLQEEYRKLGPLSFAEINVLIC FFLLVILWFSRDPGFMPGWLTVAWVEGETKYVSDATVAIFVATLLFI VPSQKPKFNFRSQTEEERKTPFYPPPLLDWKVTQEKVPWGIVLLLGG GFALAKGSEASGLSVWMGKQMEPLHAVPPAAITLILSLLVAVFTEC TSNVATTTLFLPIFASMSRSIGLNPLYIMLPCTLSASFAFMLPVATPPN AIVFTYGHLKVADMVKTGVIMNIIGVFCVFLAVNTWGRAIFDLDHF PDWANVTHIET 370 MYRALRLLARSRPLVRAPAAALASAPGLGGAAVPSFWPPNAARMA FH SQNSFRIEYDTFGELKVPNDKYYGAQTVRSTMNFKIGGVTERMPTP VIKAFGILKRAAAEVNQDYGLDPKIANAIMKAADEVAEGKLNDHFP LVVWQTGSGTQTNMNVNEVISNRAIEMLGGELGSKIPVHPNDHVN KSQSSNDTFPTAMHIAAAIEVHEVLLPGLQKLHDALDAKSKEFAQII KIGRTHTQDAVPLTLGQEFSGYVQQVKYAMTRIKAAMPRIYELAAG GTAVGTGLNTRIGFAEKVAAKVAALTGLPFVTAPNKFEALAAHDA LVELSGAMNTTACSLMKIANDIRFLGSGPRSGLGELILPENEPGSSIM PGKVNPTQCEAMTMVAAQVMGNHVAVTVGGSNGHFELNVFKPM MIKNVLHSARLLGDASVSFTENCVVGIQANTERINKLMNESLMLVT ALNPHIGYDKAAKIAKTAHKNGSTLKETAIELGYLTAEQFDEWVKP KDMLGPK 371 MWRVCARRAQNVAPWAGLEARWTALQEVPGTPRVTSRSGPAPAR DLAT RNSVTTGYGGVRALCGWTPSSGATPRNRLLLQLLGSPGRRYYSLPP HQKVPLPSLSPTMQAGTIARWEKKEGDKINEGDLIAEVETDKATVG FESLEECYMAKILVAEGTRDVPIGAIICITVGKPEDIEAFKNYTLDSSA APTPQAAPAPTPAATASPPTPSAQAPGSSYPPHMQVLLPALSPTMTM GTVQRWEKKVGEKLSEGDLLAEIETDKATIGFEVQEEGYLAKILVPE GTRDVPLGTPLCIIVEKEADISAFADYRPTEVTDLKPQVPPPTPPPVA AVPPTPQPLAPTPSAPCPATPAGPKGRVFVSPLAKKLAVEKGIDLTQ VKGTGPDGRITKKDIDSFVPSKVAPAPAAVVPPTGPGMAPVPTGVFT DIPISNIRRVIAQRLMQSKQTIPHYYLSIDVNMGEVLLVRKELNKILE GRSKISVNDFIIKASALACLKVPEANSSWMDTVIRQNHVVDVSVAV STPAGLITPIVFNAHIKGVETIANDVVSLATKAREGKLQPHEFQGGTF TISNLGMFGIKNFSAIINPPQACILAIGASEDKLVPADNEKGFDVASM MSVTLSCDHRVVDGAVGAQWLAEFRKYLEKPITMLL 372 MAGALVRKAADYVRSKDFRDYLMSTHFWGPVANWGLPIAAINDM MPC1 KKSPEIISGRMTFALCCYSLTFMRFAYKVQPRNWLLFACHATNEVA QLIQGGRLIKHEMTKTASA 373 MRKMLAAVSRVLSGASQKPASRVLVASRNFANDATFEIKKCDLHR PDHA1 LEEGPPVTTVLTREDGLKYYRMMQTVRRMELKADQLYKQKIIRGF CHLCDGQEACCVGLEAGINPTDHLITAYRAHGFTFTRGLSVREILAE LTGRKGGCAKGKGGSMHMYAKNFYGGNGIVGAQVPLGAGIALAC KYNGKDEVCLTLYGDGAANQGQIFEAYNMAALWKLPCIFICENNR YGMGTSVERAAASTDYYKRGDFIPGLRVDGMDILCVREATRFAAA YCRSGKGPILMELQTYRYHGHSMSDPGVSYRTREEIQEVRSKSDPIM LLKDRMVNSNLASVEELKEIDVEVRKEIEDAAQFATADPEPPLEELG YHIYSSDPPFEVRGANQWIKFKSVS 374 MAAVSGLVRRPLREVSGLLKRRFHWTAPAALQVTVRDAINQGMDE PDHB ELERDEKVFLLGEEVAQYDGAYKVSRGLWKKYGDKRIIDTPISEMG FAGIAVGAAMAGLRPICEFMTFNFSMQAIDQVINSAAKTYYMSGGL QPVPIVFRGPNGASAGVAAQHSQCFAAWYGHCPGLKVVSPWNSED AKGLIKSAIRDNNPVVVLENELMYGVPFEFPPEAQSKDFLIPIGKAKI ERQGTHITVVSHSRPVGHCLEAAAVLSKEGVECEVINMRTIRPMDM ETIEASVMKTNHLVTVEGGWPQFG VGAEICARIMEGPAFNFLDAPAVRVTGADVPMPYAKILEDNSIPQVK DIIFAIKKTLNI 375 MAASWRLGCDPRLLRYLVGFPGRRSVGLVKGALGWSVSRGANWR PDHX WFHSTQWLRGDPIKILMPSLSPTMEEGNIVKWLKKEGEAVSAGDAL CEIETDKAVVTLDASDDGILAKIVVEEGSKNIRLGSLIGLIVEEGEDW KHVEIPKDVGPPPPVSKPSEPRPSPEPQISIPVKKEHIPGTLRFRLSPAA RNILEKHSLDASQGTATGPRGIFTKEDALKLVQLKQTGKITESRPTP APTATPTAPSPLQATAGPSYPRPVIPPVSTPGQPNAVGTFTEIPASNIR RVIAKRLTESKSTVPHAYATADCDLGAVLKVRQDLVKDDIKVSVN DFIIKAAAVTLKQMPDVNVSWDGEGPKQLPFIDISVAVATDKGLLTP IIKDAAAKGIQEIADSVKALSKKARDGKLLPEEYQGGSFSISNLGMF GIDEFTAVINPPQACILAVGRFRPVLKLTEDEEGNAKLQQRQLITVT MSSDSRVVDDELATRFLKSFKANLENPIRLA 376 MPAPTQLFFPLIRNCELSRIYGTACYCHHKHLCCSSSYIPQSRLRYTP PDP1 HPAYATFCRPKENWWQYTQGRRYASTPQKFYLTPPQVNSILKANE YSFKVPEFDGKNVSSILGFDSNQLPANAPIEDRRSAATCLQTRGMLL GVFDGHAGCACSQAVSERLFYYIAVSLLPHETLLEIENAVESGRALL PILQWHKHPNDYFSKEASKLYFNSLRTYWQELIDLNTGESTDIDVKE ALINAFKRLDNDISLEAQVGDPNSFLNYLVLRVAFSGATACVAHVD GVDLHVANTGDSRAMLGVQEEDGSWSAVTLSNDHNAQNERELER LKLEHPKSEAKSVVKQDRLLGLLMPFRAFGDVKFKWSIDLQKRVIE SGPDQLNDNEYTKFIPPNYHTPPYLTAEPEVTYHRLRPQDKFLVLAT DGLWETMHRQDVVRIVGEYLTGMHHQQPIAVGGYKVTLGQMHGL LTERRTKMSSVFEDQNAATHLIRHAVGNNEFGTVDHERLSKMLSLP EELARMYRDDITIIVVQFNSHVVGAYQNQE 377 MLEKFCNSTFWNSSFLDSPEADLPLCFEQTVLVWIPLGYLWLLAPW ABCC2 QLLHVYKSRTKRSSTTKLYLAKQVFVGFLLILAAIELALVLTEDSGQ ATVPAVRYTNPSLYLGTWLLVLLIQYSRQWCVQKNSWFLSLFWILS ILCGTFQFQTLIRTLLQGDNSNLAYSCLFFISYGFQILILIFSAFSENNE SSNNPSSIASFLSSITYSWYDSIILKGYKRPLTLEDVWEVDEEMKTKT LVS KFETHMKRELQKARRALQRRQEKSSQQNSGARLPGLNKNQSQSQD ALVLEDVEKKKKKSGTKKDVPKSWLMKALFKTFYMVLLKSFLLKL VNDIFTFVSPQLLKLLISFASDRDTYLWIGYLCAILLFTAALIQSFCLQ CYFQLCFKLGVKVRTAIMASVYKKALTLSNLARKEYTVGETVNLM SVDAQKLMDVTNFMHMLWSSVLQIVLSIFFLWRELGPSVLAGVGV MVLVIPINAILSTKSKTIQVKNMKNKDKRLKIMNEILSGIKILKYFAW EPSFRDQVQNLRKKELKNLLAFS QLQCVVIFVFQLTPVLVSVVTFSVYVLVDSNNILDAQKAFTSITLFNI LRFPLSMLPMMISSMLQASVSTERLEKYLGGDDLDTSAIRHDCNFD KAMQFSEASFTWEHDSEATVRDVNLDIMAGQLVAVIGPVGSGKSSL ISAMLGEMENVHGHITIKGTTAYVPQQSWIQNGTIKDNILFGTEFNE KRYQQVLEACALLPDLEMLPGGDLAEIGEKGINLSGGQKQRISLAR ATYQNLDIYLLDDPLSAVDAHVGKHIFNKVLGPNGLLKGKTRLLVT HSMHFLPQVDEIVVLGNGTIV EKGSYSALLAKKGEFAKNLKTFLRHTGPEEEATVHDGSEEEDDDYG LISSVEEIPEDAASITMRRENSFRRTLSRSSRSNGRHLKSLRNSLKTRN VNSLKEDEELVKGQKLIKKEFIETGKVKFSIYLEYLQAIGLFSIFFIILA FVMNSVAFIGSNLWLSAWTSDSKIFNSTDYPASQRDMRVGVYGAL GLAQGIFVFIAHFWSAFGFVHASNILHKQLLNNILRAPMRFFDTTPT GRI VNRFAGDISTVDDTLPQSLRSWITCFLGIISTLVMICMATPVFTIIVIPL GIIYVSVQMFYVSTSRQLRRLDSVTRSPIYSHFSETVSGLPVIRAFEH QQRFLKHNEVRIDTNQKCVFSWITSNRWLAIRLELVGNLTVFFSAL MMVIYRDTLSGDTVGFVLSNALNITQTLNWLVRMTSEIETNIVAVE RITEYTKVENEAPWVTDKRPPPDWPSKGKIQFNNYQVRYRPELDLV LRGI TCDIGSMEKIGVVGRTGAGKSSLTNCLFRILEAAGGQIIIDGVDIASIG LHDLREKLTIIPQDPILFSGSLRMNLDPFNNYSDEEIWKALELAHLKS FVASLQLGLSHEVTEAGGNLSIGQRQLLCLGRALLRKSKILVLDEAT AAVDLETDNLIQTTIQNEFAHCTVITIAHRLHTIMDSDKVMVLDNGK IIECGSPEELLQIPGPFYFMAKEAGIENVNSTKF 378 MDQNQHLNKTAEAQPSENKKTRYCNGLKMFLAALSLSFIAKTLGAI SLCO1B1 IMKSSIIHIERRFEISSSLVGFIDGSFEIGNLLVIVFVSYFGSKLHRPKLI GIGCFIMGIGGVLTALPHFFMGYYRYSKETNINSSENSTSTLSTCLIN QILSLNRASPEIVGKGCLKESGSYMWIYVFMGNMLRGIGETPIVPLG LSYIDDFAKEGHSSLYLGILNAIAMIGPIIGFTLGSLFSKMYVDIGYV DLSTIRITPTDSRWVGAWWLNFLVSGLFSHSSIPFFFLPQTPNKPQKE RKASLSLHVLETNDEKDQTANLTNQGKNITKNVTGFFQSFKSILTNP LYVMFVLLTLLQVSSYIGAFTYVFKYVEQQYGQPSSKANILLGVITIP IFASGMFLGGYIIKKFKLNTVGIAKFSCFTAVMSLSFYLLYFFILCEN KSVAGLTMTYDGNNPVTSHRDVPLSYCNSDCNCDESQWEPVCGNN GITYISPCLAGCKSSSGNKKPIVFYNCSCLEVTGLQNRNYSAHLGEC PRDDACTRKFYFFVAIQVLNLFFSALGGTSHVMLIVKIVQPELKSLA LGFHSMVIRALGGILAPIYFGALIDTTCIKWSTNNCGTRGSCRTYNST SFSRVYLGLSSMLRVSSLVLYIILIYAMKKKYQEKDINASENGSVMD EANLESLNKNKHFVPSAGADSETHC 379 MDQHQHLNKTAESASSEKKKTRRCNGFKMFLAALSFSYIAKALGGI SLCO1B3 IMKISITQIERRFDISSSLAGLIDGSFEIGNLLVIVFVSYFGSKLHRPKLI GIGCLLMGTGSILTSLPHFFMGYYRYSKETHINPSENSTSSLSTCLINQ TLSFNGTSPEIVEKDCVKESGSHMWIYVFMGNMLRGIGETPIVPLGIS YIDDFAKEGHSSLYLGSLNAIGMIGPVIGFALGSLFAKMYVDIGYV DLSTIRITPKDSRWVGAWWLGFLVSGLFSHSSIPFFFLPKNPNKPQKE RKISLSLHVLKTNDDRNQTANLTNQGKNVTKNVTGFFQSLKSILTNP LYVIFLLLTLLQVSSFIGSFTYVFKYMEQQYGQSASHANFLLGIITIPT VATGMFLGGFIIKKFKLSLVGIAKFSFLTSMISFLFQLLYFPLICESKS VAGLTLTYDGNNSVASHVDVPLSYCNSECNCDESQWEPVCGNNGI TYLSPCLAGCKSSSGIKKHTVFYNCSCVEVTGLQNRNYSAHLGECP RDNTCTRKFFIYVAIQVINSLFSATGGTTFILLTVKIVQPELKALAMG FQSMVIRTLGGILAPIYFGALIDKTCMKWSTNSCGAQGACRIYNSVF FGRVYLGLSIALRFPALVLYIVFIFAMKKKFQGKDTKASDNERKVM DEANLEFLNNGEHFVPSAGTDSKTCNLDMQDNAAAN 380 MGEPGQSPSPRSSHGSPPTLSTLTLLLLLCGHAHSQCKILRCNAEYVS HFE2 STLSLRGGGSSGALRGGGGGGRGGGVGSGGLCRALRSYALCTRRT ARTCRGDLAFHSAVHGIEDLMIQHNCSRQGPTAPPPPRGPALPGAGS GLPAPDPCDYEGRFSRLHGRPPGFLHCASFGDPHVRSFHHHFHTCR VQGAWPLLDNDFLFVQATSSPMALGANATATRKLTIIFKNMQECID QKVYQAEVDNLPVAFEDGSINGGDRPGGSSLSIQTANPGNHVEIQA AYIGTTIIIRQTAGQLSFSIKVAEDVAMAFSAEQDLQLCVGGCPPSQR LSRSERNRRGAITIDTARRLCKEGLPVEDAYFHSCVFDVLISGDPNFT VAAQAALEDARAFLPDLEKLHLFPSDAGVPLSSATLLAPLLSGLFVL WLCIQ 381 MHQRHPRARCPPLCVAGILACGFLLGCWGPSHFQQSCLQALEPQAV ADAMTS13 SSYLSPGAPLKGRPPSPGFQRQRQRQRRAAGGILHLELLVAVGPDVF QAHQEDTERYVLTNLNIGAELLRDPSLGAQFRVHLVKMVILTEPEG APNITANLTSSLLSVCGWSQTINPEDDTDPGHADLVLYITRFDLELPD GNRQVRGVTQLGGACSPTWSCLITEDTGFDLGVTIAHEIGHSFGLEH DGAPGSGCGPSGHVMASDGAAPRAGLAWSPCSRRQLLSLLSAGRA RCVWDPPRPQPGSAGHPPDAQPGLYYSANEQCRVAFGPKAVACTF AREHLDMCQALSCHTDPLDQSSCSRLLVPLLDGTECGVEKWCSKG RCRSLVELTPIAAVHGRWSSWGPRSPCSRSCGGGVVTRRRQCNNPR PAFGGRACVGADLQAEMCNTQACEKTQLEFMSQQCARTDGQPLRS SPGGASFYHWGAAVPHSQGDALCRHMCRAIGESFIMKRGDSFLDG TRCMPSGPREDGTLSLCVSGSCRTFGCDGRMDSQQVWDRCQVCGG DNSTCSPRKGSFTAGRAREYVTFLTVTPNLTSVYIANHRPLFTHLAV RIGGRYVVAGKMSISPNTTYPSLLEDGRVEYRVALTEDRLPRLEEIRI WGPLQEDADIQVYRRYGEEYGNLTRPDITFTYFQPKPRQAWVWAA VRGPCSVSCGAGLRWVNYSCLDQARKELVETVQCQGSQQPPAWPE ACVLEPCPPYWAVGDFGPCSASCGGGLRERPVRCVEAQGSLLKTLP PARCRAGAQQPAVALETCNPQPCPARWEVSEPSSCTSAGGAGLALE NETCVPGADGLEAPVTEGPGSVDEKLPAPEPCVGMSCPPGWGHLD ATSAGEKAPSPWGSIRTGAQAAHVWTPAAGSCSVSCGRGLMELRF LCMDSALRVPVQEELCGLASKPGSRREVCQAVPCPARWQYKLAAC SVSCGRGVVRRILYCARAHGEDDGEEILLDTQCQGLPRPEPQEACSL EPCPPRWKVMSLGPCSASCGLGTARRSVACVQLDQGQDVEVDEAA CAALVRPEASVPCLIADCTYRWHVGTWMECSVSCGDGIQRRRDTC LGPQAQAPVPADFCQHLPKPVTVRGCWAGPCVGQGTPSLVPHEEA AAPGRTTATPAGASLEWSQARGLLFSPAPQPRRLLPGPQENSVQSSA CGRQHLEPTGTIDMRGPGQADCAVAIGRPLGEVVTLRVLESSLNCS AGDMLLLWGRLTWRKMCRKLLDMTFSSKTNTLVVRQRCGRPGGG VLLRYGSQLAPETFYRECDMQLFGPWGEIVSPSLSPATSNAGGCRLF INVAPHARIAIHALATNMGAGTEGANASYILIRDTHSLRTTAFHGQQ VLYWESESSQAEMEFSEGFLKAQASLRGQYWTLQSWVPEMQDPQS WKGKEGT 382 MSRPLSDQEKRKQISVRGLAGVENVTELKKNFNRHLHFTLVKDRN PYGM VATPRDYYFALAHTVRDHLVGRWIRTQQHYYEKDPKRIYYLSLEFY MGRTLQNTMVNLALENACDEATYQLGLDMEELEEIEEDAGLGNGG LGRLAACFLDSMATLGLAAYGYGIRYEFGIFNQKISGGWQMEEAD DWLRYGNPWEKARPEFTLPVHFYGHVEHTSQGAKWVDTQVVLAM PYDTPVPGYRNNVVNTMRLWSAKAPNDFNLKDFNVGGYIQAVLD RNLAENISRVLYPNDNFFEGKELRLKQEYFVVAATLQDIIRRFKSSK FGCRDPVRTNFDAFPDKVAIQLNDTHPSLAIPELMRILVDLERM DWDKAWDVTVRTCAYTNHTVLPEALERWPVHLLETLLPRHLQIIYE INQRFLNRVAAAFPGDVDRLRRMSLVEEGAVKRINMAHLCIAGSHA VNGVARIHSEILKKTIFKDFYELEPHKFQNKTNGITPRRWLVLCNPG LAEVIAERIGEDFISDLDQLRKLLSFVDDEAFIRDVAKVKQENKLKF AAYLEREYKVHINPNSLFDIQVKRIHEYKRQLLNCLHVITLYNRIKR EPNKFFVPRTVMIGGKAAPGYHMAKMIIRLVTAIGDVVNHDPAVG DRLRVIFLENYRVSLAEKVIPAADLSEQISTAGTEASGTGNMKFMLN GALTIGTMDGANVEMAEEAGEENFFIFGMRVEDVDKLDQRGYNAQ EYYDRIPELRQVIEQLSSGFFSPKQPDLFKDIVNMLMHHDRFKVFAD YEDYIKCQEKVSALYKNPREWTRMVIRNIATSGKFSSDRTIAQYARE IWGVEPSRQRLPAPDEAI 383 MLSFVDTRTLLLLAVTLCLATCQSLQEETVRKGPAGDRGPRGERGP COL1A2 PGPPGRDGEDGPTGPPGPPGPPGPPGLGGNFAAQYDGKGVGLGPGP MGLMGPRGPPGAAGAPGPQGFQGPAGEPGEPGQTGPAGARGPAGP PGKAGEDGHPGKPGRPGERGVVGPQGARGFPGTPGLPGFKGIRGHN GLDGLKGQPGAPGVKGEPGAPGENGTPGQTGARGLPGERGRVGAP GPAGARGSDGSVGPVGPAGPIGSAGPPGFPGAPGPKGEIGAVGNAG PAGPAGPRGEVGLPGLSGPVGPPGNP GANGLTGAKGAAGLPGVAGAPGLPGPRGIPGPVGAAGATGARGLV GEPGPAGSKGESGNKGEPGSAGPQGPPGPSGEEGKRGPNGEAGSAG PPGPPGLRGSPGSRGLPGADGRAGVMGPPGSRGASGPAGVRGPNGD AGRPGEPGLMGPRGLPGSPGNIGPAGKEGPVGLPGIDGRPGPIGPAG ARGEPGNIGFPGPKGPTGDPGKNGDKGHAGLAGARGAPGPDGNNG AQGPPGPQGVQGGKGEQGPPGPPGFQGLPGPSGPAGEVGKPGERGL HGEFGLPGPAGPRGERGPPGESGAA GPTGPIGSRGPSGPPGPDGNKGEPGVVGAVGTAGPSGPSGLPGERGA AGIPGGKGEKGEPGLRGEIGNPGRDGARGAPGAVGAPGPAGATGD RGEAGAAGPAGPAGPRGSPGERGEVGPAGPNGFAGPAGAAGQPGA KGERGAKGPKGENGVVGPTGPVGAAGPAGPNGPPGPAGSRGDGGP PGMTGFPGAAGRTGPPGPSGISGPPGPPGPAGKEGLRGPRGDQGPV GRTGEVGAVGPPGFAGEKGPSGEAGTAGPPGTPGPQGLLGAPGILG LPGSRGERGLPGVAGAVGEPGPLGIAGPPGARGPPGAVGSPGVNGA PGEAGRDGNPGNDGPPGRDGQPGHKGERGYPGNIGPVGAAGAPGP HGPVGPAGKHGNRGETGPSGPVGPAGAVGPRGPSGPQGIRGDKGEP GEKGPRGLPGLKGHNGLQGLPGIAGHHGDQGAPGSVGPAGPRGPA GPSGPAGKDGRTGHPGTVGPAGIRGPQGHQGPAGPPGPPGPPGPPG VSGGGYDFGYDGDFYRADQPRSAPSLRPKDYEVDATLKSLNNQIET LLTPEGSRKNPARTCRDLRLSHPEWSSGYYWIDPNQGCTMDAIKVY CDFSTGETCIRAQPENIPAKNWYRSSKDKKHVWLGETINAGSQFEY NVEGVTSKEMATQLAFMRLLANYASQNITYHCKNSIAYMDEETGN LKKAVILQGSNDVELVAEGNSRFTYTVLVDGCSKKTNEWGKTIIEY KTNKPSRLPFLDIAPLDIGGADQEFFVDIGPVCFK 384 MNNLLCCALVFLDISIKWTTQETFPPKYLHYDEETSHQLLCDKCPPG TNFRSF11B TYLKQHCTAKWKTVCAPCPDHYYTDSWHTSDECLYCSPVCKELQY VKQECNRTHNRVCECKEGRYLEIEFCLKHRSCPPGFGVVQAGTPER NTVCKRCPDGFFSNETSSKAPCRKHTNCSVFGLLLTQKGNATHDNI CSGNSESTQKCGIDVTLCEEAFFRFAVPTKFTPNWLSVLVDNLPGTK VNAESVERIKRQHSSQEQTFQLLKLWKHQNKDQDIVKKIIQDIDLCE NSVQRHIGHANLTFEQLRSLMESLPGKKVGAEDIEKTIKACKPSDQI LKLLSLWRIKNGDQDTLKGLMHALKHSKTYHFPKTVTQSLKKTIRF LHSFTMYKLYQKLFLEMIGNQVQSVKISCL 385 MAQQANVGELLAMLDSPMLGVRDDVTAVFKENLNSDRGPMLVNT TSC1 LVDYYLETSSQPALHILTTLQEPHDKHLLDRINEYVGKAATRLSILSL LGHVIRLQPSWKHKLSQAPLLPSLLKCLKMDTDVVVLTTGVLVLIT MLPMIPQSGKQHLLDFFDIFGRLSSWCLKKPGHVAEVYLVHLHASV YALFHRLYGMYPCNFVSFLRSHYSMKENLETFEEVVKPMMEHVRI HPELVTGSKDHELDPRRWKRLETHDVVIECAKISLDPTEASYEDGYS VSHQISARFPHRSADVTTSPYADT QNSYGCATSTPYSTSRLMLLNMPGQLPQTLSSPSTRLITEPPQATLW SPSMVCGMTTPPTSPGNVPPDLSHPYSKVFGTTAGGKGTPLGTPATS PPPAPLCHSDDYVHISLPQATVTPPRKEERMDSARPCLHRQHHLLND RGSEEPPGSKGSVTLSDLPGFLGDLASEEDSIEKDKEEAAISRELSEIT TAEAEPVVPRGGFDSPFYRDSLPGSQRKTHSAASSSQGASVNPEPLH SSL DKLGPDTPKQAFTPIDLPCGSADESPAGDRECQTSLETSIFTPSPCKIP PPTRVGFGSGQPPPYDHLFEVALPKTAHHFVIRKTEELLKKAKGNTE EDGVPSTSPMEVLDRLIQQGADAHSKELNKLPLPSKSVDWTHFGGS PPSDEIRTLRDQLLLLHNQLLYERFKRQQHALRNRRLLRKVIKAAAL EEHNAAMKDQLKLQEKDIQMWKVSLQKEQARYNQLQEQRDTMVT KLHSQIRQLQHDREEFYNQSQELQTKLEDCRNMIAELRIELKKANN KVCHTELLLSQVSQKLSNSESVQQQMEFLNRQLLVLGEVNELYLEQ LQNKHSDTTKEVEMMKAAYRKELEKNRSHVLQQTQRLDTSQKRIL ELESHLAKKDHLLLEQKKYLEDVKLQARGQLQAAESRYEAQKRIT QVFELEILDLYGRLEKDGLLKKLEEEKAEAAEAAEERLDCCNDGCS DSMVGHNEEASGHNGETKTPRPSSARGSSGSRGGGGSSSSSSELSTP EKPPHQRAGPFSSRWETTMGEASASIPTTVGSLPSSKSFLGMKAREL FRNKSESQCDEDGMTSSLSESLKTELGKDLGVEAKIPLNLDGPHPSP PTPDSVGQLHIMDYNETHHEHS 386 MAKPTSKDSGLKEKFKILLGLGTPRPNPRSAEGKQTEFIITAEILRELS TSC2 MECGLNNRIRMIGQICEVAKTKKFEEHAVEALWKAVADLLQPERPL EARHAVLALLKAIVQGQGERLGVLRALFFKVIKDYPSNEDLHERLE VFKALTDNGRHITYLEEELADFVLQWMDVGLSSEFLLVLVNLVKFN SCYLDEYIARMVQMICLLCVRTASSVDIEVSLQVLDAVVCYNCLPA ESLPLFIVTLCRTINVKELCEPCWKLMRNLLGTHLGHSAIYNMCHL MEDRAYMEDAPLLRGAVFFVGMALWGAHRLYSLRNSPTSVLPSFY QAMACPNEVVSYEIVLSITRLIKKYRKELQVVAWDILLNIIERLLQQL QTLDSPELRTIVHDLLTTVEELCDQNEFHGSQERYFELVERCADQRP ESSLLNLISYRAQSIHPAKDGWIQNLQALMERFFRSESRGAVRIKVL DVLSFVLLINRQFYEEELINSVVISQLSHIPEDKDHQVRKLATQLLVD LAEGCHTHHFNSLLDIIEKVMARSLSPPPELEERDVAAYSASLEDVK TAVLGLLVILQTKLYTLPASHATRVYEMLVSHIQLHYKHSYTLPIAS SIRLQAFDFLLLLRADSLHRLGLPNKDGVVRFSPYCVCDYMEPERGS E1(KTSGPLSPPTGPPGPAPAGPAVRLGSVPYSLLFRVLLQCLKQESD WKVLKLVLGRLPESLRYKVLIFTSPCSVDQLCSALCSMLSGPKTLER LRGAPEGFSRTDLHLAVVPVLTALISYHNYL DKTKQREMVYCLEQGLIHRCASQCVVALSICSVEMPDIIIKALPVLV VKLTHISATASMAVPLLEFLSTLARLPHLYRNFAAEQYASVFAISLP YTNPSKFNQYIVCLAHHVIAMWFIRCRLPFRKDFVPFITKGLRSNVL LSFDDTPEKDSFRARSTSLNERPKSLRIARPPKQGLNNSPPVKEFKES SAAEAFRCRSISVSEHVVRSRIQTSLTSASLGSADENSVAQADDSLK NLHL ELTETCLDMMARYVFSNFTAVPKRSPVGEFLLAGGRTKTWLVGNK LVTVTTSVGTGTRSLLGLDSGELQSGPESSSSPGVHVRQTKEAPAKL ESQAGQQVSRGARDRVRSMSGGHGLRVGALDVPASQFLGSATSPG PRTAPAAKPEKASAGTRVPVQEKTNLAAYVPLLTQGWAEILVRRPT GNTSWLMSLENPLSPFSSDINNMPLQELSNALMAAERFKEHRDTAL YKSLSVPAASTAKPPPLPRSNTVASFSSLYQSSCQGQLHRSVSWADS AVVMEEGSPGEVPVLVEPPGLEDV EAALGMDRRTDAYSRSSSVSSQEEKSLHAEELVGRGIPIERVVSSEG GRPSVDLSFQPSQPLSKSSSSPELQTLQDILGDPGDKADVGRLSPEVK ARSQSGTLDGESAAWSASGEDSRGQPEGPLPSSSPRSPSGLRPRGYTI SDSAPSRRGKRVERDALKSRATASNAEKVPGINPSFVFLQLYHSPFF GDESNKPILLPNESQSFERSVQLLDQIPSYDTHKIAVLYVGEGQSNSE LA ILSNEHGSYRYTEFLTGLGRLIELKDCQPDKVYLGGLDVCGEDGQFT YCWHDDIMQAVFHIATLMPTKDVDKHRCDKKRHLGNDFVSIVYND SGEDFKLGTIKGQFNFVHVIVTPLDYECNLVSLQCRKDMEGLVDTS VAKIVSDRNLPFVARQMALHANMASQVHHSRSNPTDIYPSKWIARL RHIKRLRQRICEEAAYSNPSLPLVHPPSHSKAPAQTPAEPTPGYEVG QRKRLISSVEDFTEFV 387 MAAKSQPNIPKAKSLDGVTNDRTASQGQWGRAWEVDWFSLASVIF DHCR7 LLLFAPFIVYYFIMACDQYSCALTGPVVDIVTGHARLSDIWAKTPPIT RKAAQLYTLWVTFQVLLYTSLPDFCHKFLPGYVGGIQEGAVTPAGV VNKYQINGLQAWLLTHLLWFANAHLLSWFSPTIIFDNWIPLLWCAN ILGYAVSTFAMVKGYFFPTSARDCKFTGNFFYNYMMGIEFNPRIGK WFDFKLFFNGRPGIVAWTLINLSFAAKQRELHSHVTNAMVLVNVL QAIYVIDFFWNETWYLKTIDICHD HFGWYLGWGDCVWLPYLYTLQGLYLVYHPVQLSTPHAVGVLLLG LVGYYIFRVANHQKDLFRRTDGRCLIWGRKPKVIECSYTSADGQRH HSKLLVSGFWGVARHFNYVGDLMGSLAYCLACGGGHLLPYFYIIY MAILLTHRCLRDEHRCASKYGRDWERYTAAVPYRLLPGIF 388 MSLSNKLTLDKLDVKGKRVVMRVDFNVPMKNNQITNNQRIKAAVP PGK1 SIKFCLDNGAKSVVLMSHLGRPDGVPMPDKYSLEPVAVELKSLLGK DVLFLKDCVGPEVEKACANPAAGSVILLENLRFHVEEEGKGKDASG NKVKAEPAKIEAFRASLSKLGDVYVNDAFGTAHRAHSSMVGVNLP QKAGGFLMKKELNYFAKALESPERPFLAILGGAKVADKIQLINNML DKVNEMIIGGGMAFTFLKVLNNMEIGTSLFDEEGAKIVKDLMSKAE KNGVKITLPVDFVTADKFDENAKTGQATVASGIPAGWMGLDCGPE SSKKYAEAVTRAKQIVWNGPVGVFEWEAFARGTKALMDEVV KATSRGCITIIGGGDTATCCAKWNTEDKVSHVSTGGGASLELLEGK VLPGVDALSNI 389 MGTSALWALWLLLALCWAPRESGATGTGRKAKCEPSQFQCTNGR VLDLR CITLLWKCDGDEDCVDGSDEKNCVKKTCAESDFVCNNGQCVPSRW KCDGDPDCEDGSDESPEQCHMRTCRIHEISCGAHSTQCIPVSWRCD GENDCDSGEDEENCGNITCSPDEFTCSSGRCISRNFVCNGQDDCSDG SDELDCAPPTCGAHEFQCSTSSCIPISWVCDDDADCSDQSDESLEQC GRQPVIHTKCPASEIQCGSGECIHKKWRCDGDPDCKDGSDEVNCPS RTCRPDQFECEDGSCIHGSRQCNGI RDCVDGSDEVNCKNVNQCLGPGKFKCRSGECIDISKVCNQEQDCR DWSDEPLKECHINECLVNNGGCSHICKDLVIGYECDCAAGFELIDRK TCGDIDECQNPGICSQICINLKGGYKCECSRGYQMDLATGVCKAVG KEPSLIFTNRRDIRKIGLERKEYIQLVEQLRNTVALDADIAAQKLFW ADLSQKAIFSASIDDKVGRHVKMIDNVYNPAAIAVDWVYKTIYWT DAASKTISVATLDGTKRKFLFNSDLREPASIAVDPLSGFVYWSDWG EPAKIEKAGMNGFDRRPLVTADIQ WPNGITLDLIKSRLYWLDSKLHMLSSVDLNGQDRRIVLKSLEFLAHP LALTIFEDRVYWIDGENEAVYGANKFTGSELATLVNNLNDAQDIIV YHELVQPSGKNWCEEDMENGGCEYLCLPAPQINDHSPKYTCSCPSG YNVEENGRDCQSTATTVTYSETKDTNTTEISATSGLVPGGINVTTAV SEVSVPPKGTSAAWAILPLLLLVMAAVGGYLMWRNWQHKNMKS MNFDNPVYLKTTEEDLSIDIGRHSASVGHTYPAISVVSTDDDLA 390 MEPSSLELPADTVQRIAAELKCHPTDERVALHLDEEDKLRHFRECFY KYNU IPKIQDLPPVDLSLVNKDENAIYFLGNSLGLQPKMVKTYLEEELDKW AKIAAYGHEVGKRPWITGDESIVGLMKDIVGANEKEIALMNALTVN LHLLMLSFFKPTPKRYKILLEAKAFPSDHYAIESQLQLHGLNIEESMR MIKPREGEETLRIEDILEVIEKEGDSIAVILFSGVHFYTGQHFNIPAITK AGQAKGCYVGFDLAHAVGNVELYLHDWGVDFACWCSYKYLNAG AGGIAGAFIHEKHAHTIKPALVGWFGHELSTRFKMDNKLQLIPGVC GFRISNPPILLVCSLHASLEIFKQATMKALRKKSVLLTGYLEYLIKHN YGKDKAATKKPVVNIITPSHVEERGCQLTITFSVPNKDVFQELEKRG VVCDKRNPNGIRVAPVPLYNSFHDVYKFTNLLTSILDSAETKN 391 MFPGCPRLWVLVVLGTSWVGWGSQGTEAAQLRQFYVAAQGISWS F5 YRPEPTNSSLNLSVTSFKKIVYREYEPYFKKEKPQSTISGLLGPTLYA EVGDIIKVHFKNKADKPLSIHPQGIRYSKLSEGASYLDHTFPAEKMD DAVAPGREYTYEWSISEDSGPTHDDPPCLTHIYYSHENLIEDFNSGLI GPLLICKKGTLTEGGTQKTFDKQIVLLFAVFDESKSWSQSSSLMYTV NGYVNGTMPDITVCAHDHISWHLLGMSSGPELFSIHFNGQVLEQNH HKVSAITLVSATSTTANMTVGPEGKWIISSLTPKHLQAGMQAYIDIK NCPKKTRNLKKITREQRRHMKRWEYFIAAEEVIWDYAPVIPANMD KKYRSQHLDNFSNQIGKHYKKVMYTQYEDESFTKHTVNPNMKED GILGPIIRAQVRDTLKIVFKNMASRPYSIYPHGVTFSPYEDEVNSSFTS GRNNTMIRAVQPGETYTYKWNILEFDEPTENDAQCLTRPYYSDVDI MRDIASGLIGLLLICKSRSLDRRGIQRAA DIEQQAVFAVFDENKSWYLEDNINKFCENPDEVKRDDPKFYESNIM STINGYVPESITTLGFCFDDTVQWHFCSVGTQNEILTIHFTGHSFIYG KRHEDTLTLFPMRGESVTVTMDNVGTWMLTSMNSSPRSKKLRLKF RDVKCIPDDDEDSYEIFEPPESTVMATRKMHDRLEPEDEESDADYD YQNRLAAALGIRSFRNSSLNQEEEEFNLTALALENGTEFVSSNTDIIV GSNYSSPSNISKFTVNNLAEPQKAPSHQQATTAGSPLRHLIGKNSVL NSSTAEHSSPYSEDPIEDPLQPDVTGIRLLSLGAGEFKSQEHAKHKGP KVERDQAAKHRFSWMKLLAHKVGRHLSQDTGSPSGMRPWEDLPS QDTGSPSRMRPWKDPPSDLLLLKQSNSSKILVGRWHLASEKGSYEII QDTDEDTAVNNWLISPQNASRAWGESTPLANKPGKQSGHPKFPRV RHKSLQVRQDGGKSRLKKSQFLIKTRKKKKEKHTHHAPLSPRTFHP LRSEAYNTFSERRLKHSLVLHKSNETSLPT DLNQTLPSMDFGWIASLPDHNQNSSNDTGQASCPPGLYQTVPPEEH YQTFPIQDPDQMHSTSDPSHRSSSPELSEMLEYDRSHKSFPTDISQMS PSSEHEVWQTVISPDLSQVTLSPELSQTNLSPDLSHTTLSPELIQRNLS PALGQMPISPDLSHTTLSPDLSHTTLSLDLSQTNLSPELSQTNLSPAL GQMPLSPDLSHTTLSLDFSQTNLSPELSHMTLSPELSQTNLSPALGQ MP ISPDLSHTTLSLDFSQTNLSPELSQTNLSPALGQMPLSPDPSHTTLSLD LSQTNLSPELSQTNLSPDLSEMPLFADLSQIPLTPDLDQMTLSPDLGE TDLSPNFGQMSLSPDLSQVTLSPDISDTTLLPDLSQISPPPDLDQIFYP SESSQSLLLQEFNESFPYPDLGQMPSPSSPTLNDTFLSKEFNPLVIVGL SKDGTDYIEIIPKEEVQSSEDDYAEIDYVPYDDPYKTDVRTNINSSRD PDNIAAWYLRSNNGNRRNYYIAAEEISWDYSEFVQRETDIEDSDDIP EDTTYKKVVFRKYLDSTFTKRDPRGEYEEHLGILGPIIRAEVDDVIQ VRFKNLASRPYSLHAHGLSYEKSSEGKTYEDDSPEWFKEDNAVQPN SSYTYVWHATERSGPESPGSACRAWAYYSAVNPEKDIHSGLIGPLLI CQKGILHKDSNMPMDMREFVLLFMTFDEKKSWYYEKKSRSSWRLT SSEMK KSHEFHAINGMIYSLPGLKMYEQEWVRLHLLNIGGSQDIHVVHFHG QTLLENGNKQHQLGVWPLLPGSFKTLEMKASKPGWWLLNTEVGE NQRAGMQTPFLIMDRDCRMPMGLSTGIISDSQIKASEFLGYWEPRL ARLNNGGSYNAWSVEKLAAEFASKPWIQVDMQKEVIITGIQTQGAK HYLKSCYTTEFYVAYSSNQINWQIFKGNSTRNVMYFNGNSDASTIK ENQFDPPIVARYIRISPTRAYNRPTLRLELQGCEVNGCSTPLGMENG KIENKQITASSFKKSWWGDYWEPFR ARLNAQGRVNAWQAKANNNKQWLEIDLLKIKKITAIITQGCKSLSS EMYVKSYTIHYSEQGVEWKPYRLKSSMVDKIFEGNTNTKGHVKNF FNPPIISRFIRVIPKTWNQSIALRLELFGCDIY 392 MGPTSGPSLLLLLLTHLPLALGSPMYSIITPNILRLESEETMVLEAHD C3 AQGDVPVTVTVHDFPGKKLVLSSEKTVLTPATNHMGNVTFTIPANR EFKSEKGRNKFVTVQATFGTQVVEKVVLVSLQSGYLFIQTDKTIYTP GSTVLYRIFTVNHKLLPVGRTVMVNIENPEGIPVKQDSLSSQNQLGV LPLSWDIPELVNMGQWKIRAYYENSPQQVFSTEFEVKEYVLPSFEVI VEPTEKFYYIYNEKGLEVTITARFLYGKKVEGTAFVIFGIQDGEQRIS LPESLKRIPIEDGSGEVVLSRKVLLDGVQNPRAEDLVGKSLYVSATV ILHSGSDMVQAERSGIPIVTSPYQIHFTKTPKYFKPGMPFDLMVFVT NPDGSPAYRVPVAVQGEDTVQSLTQGDGVAKLSINTHPSQKPLSITV RTKKQELSEAEQATRTMQALPYSTVGNSNNYLHLSVLRTELRPGET LNVNFLLRMDRAHEAKIRYYTYLIMNKGRLLKAGRQVREPGQDLV VLPLSITTDFIPSFRLVAYYTLIGASGQREVVADSVWVDVKDSCVGS LVVKSGQSEDRQPVPGQQMTLKIEGDHGARVVLVAVDKGVFVLNK KNKLTQSKIWDVVEKADIGCTPGSGKDYAGVFSDAGLTFTSSSGQQ TAQRAELQCPQPAARRRRSVQLTEKRMDKVGKYPKELRKCCEDG MRENPMRFSCQRRTRFISLGEACKKVFLDCCNYITELRRQHARASH LGLARSNLDEDIIAEENIVSRSEFPESWLWNVEDLKEPPKNGISTKLM NIFLKDSITTWEILAVSMSDKKGICVADPFEVTVMQDFFIDLRLPYSV VRNEQVEIRAVLYNYRQNQELKVRVELLHNPAFCSLATTKRRHQQ TVTIPPKSSLSVPYVIVPLKTGLQEVEVKAAVYHHFISDGVRKSLKV VPEGIRMNKTVAVRTLDPERLGREGVQKEDIPPADLSDQVPDTESET RILLQGTPVAQMTEDAVDAERLKHLIVTPSGCGEQNMIGMTPTVIA VHYLDETEQWEKFGLEKRQGALELIKKGYTQQLAFRQPSSAFAAFV KRAPSTWLTA YVVKVFSLAVNLIAIDSQVLCGAVKWLILEKQKPDGVFQEDAPVIH QEMIGGLRNNNEKDMALTAFVLISLQEAKDICEEQVNSLPGSITKAG DFLEANYMNLQRSYTVAIAGYALAQMGRLKGPLLNKFLTTAKDKN RWEDPGKQLYNVEATSYALLALLQLKDFDFVPPVVRWLNEQRYYG GGYGSTQATFMVFQALAQYQKDAPDHQELNLDVSLQLPSRSSKITH RIHWESASLLRSEETKENEGFTVTAEGKGQGTLSVVTMYHAKAKD QLTCNKFDLKVTIKPAPETEKRPQDAKNTMILEICTRYRGDQDATM SILDISMMTGFAPDTDDLKQLANGVDRYISKYELDKAFSDRNTLIIY LDKVSHSEDDCLAFKVHQYFNVELIQPGAVKVYAYYNLEESCTRFY HPEKEDGKLNKLCRDELCRCAEENCFIQKSDDKVTLEERLDKACEP GVDYVYKTRLVKVQLSNDFDEYIMAIEQTIKSGSDEVQVGQQRTFIS PIKCREALKLEEKKHYLMWGLSSDFWGEKPNLSYIIGKDTWVEHWP EEDECQDEENQKQCQDLGAFTESMVVFGCPN 393 MGPRLSVWLLLLPAALLLHEEHSRAAAKGGCAGSGCGKCDCHGV COL4A1 KGQKGERGLPGLQGVIGFPGMQGPEGPQGPPGQKGDTGEPGLPGTK GTRGPPGASGYPGNPGLPGIPGQDGPPGPPGIPGCNGTKGERGPLGP PGLPGFAGNPGPPGLPGMKGDPGEILGHVPGMLLKGERGFPGIPGTP GPPGLPGLQGPVGPPGFTGPPGPPGPPGPPGEKGQMGLSFQGPKGDK GDQGVSGPPGVPGQAQVQEKGDFATKGEKGQKGEPGFQGMPGVG EKGEPGKPGPRGKPGKDGDKGEKGSPGFPGEPGYPGLIGRQGPQGE KGEAGPPGPPGIVIGTGPLGEKGERGYPGTPGPRGEPGPKGFPGLPG QPGPPGLPVPGQAGAPGFPGERGEKGDRGFPGTSLPGPSGRDGLPGP PGSPGPPGQPGYTNGIVECQPGPPGDQGPPGIPGQPGFIGEIGEKGQK GESCLICDIDGYRGPPGPQGPPGEIGFPGQPGAKGDRGLPGRDGVAG VPGPQGTPGLIGQPGAKGEPGEFYFDLRLKGDKGDPGFPGQPGMPG RAGSPGRDGHPGLPGPKGSPGSVGLKGERGPPGGVGFPGSRGDTGP PGPPGYGPAGPIGDKGQAGFPGGPGSPGLPGPKGEPGKIVPLPGPPG AEGLPGSPGFPGPQGDRGFPGTPGRPGLPGEKGAVGQPGIGFPGPPG PKGVDGLPGDMGPPGTPGRPGFNGLPGNPGVQGQKGEPGVGLPGL KGLPGLPGIPGTPGEKGSIGVPGVPGEHGAIGPPGLQGIRGEPGPPGL PGSVGSPGVPGIGPPGARGPPGGQGPPGLSGPPGIKGEKGFPGFPGLD MPGPKGDKGAQGLPGITGQSGLPGLPGQQGAPGIPGFPGSKGEMGV MGTPGQPGSPGPVGAPGLPGEKGDHGFPGSSGPRGDPGLKGDKGD VGLPGKPGSMDKVDMGSMKGQKGDQGEKGQIGPIGEKGSRGDPGT PGVPGKDGQAGQPGQPGPKGDPGISGTPGAPGLPGPKGSVGGMGLP GTPGEKGVPGIPGPQGSPGLPGDKGAKGEKGQAGPPGIGIPGLRGEK GDQGIAGFPGSPGEKGEKGSIGIPGMPGSPGLKGSPGSVGYPGSPGLP GEKGDKGLPGLDGIPGVKGEAGLPGTPGPTGPAGQKGEPGSDGIPG SAGEKGEPGLPGRGFPGFPGAKGDKGSKGEVGFPGLAGSPGIPGSK GEQGFMGPPGPQGQPGLPGSPGHATEGPKGDRGPQGQPGLPGLPGP MGPPGLPGIDGVKGDKGNPGWPGAPGVPGPKGDPGFQGMPGIGGS PGITGSKGDMGPPGVPGFQGPKGLPGLQGIKGDQGDQGVPGAKGLP GPPGPPGPYDIIKGEPGLPGPEGPPGLKGLQGLPGPKGQQGVTGLVG IPGPPGIPGFDGAPGQKGEMGPAGPTGPRGFPGPPGPDGLPGSMGPP GTPSVDHGFLVTRHSQTIDDPQCPSGTKILYHGYSLLYVQGNERAH GQDLGTAGSCLRKFSTMPFLFCNINNVCNFASRNDYSYWLSTPEPM PMSMAPITGENIRPFISRCAVCEAPAMVMAVHSQTIQIPPCPSGWSSL WIGYSFVMHTSAGAEGSGQALASPGSCLEEFRSAPFIECHGRGTCNY YANAYSFWLATIERSEMFKKPTPSTLKAGELRTHVSRCQVCMRRT 394 MRLLAKIICLMLWAICVAEDCNELPPRRNTEILTGSWSDQTYPEGTQ CFH AIYKCRPGYRSLGNVIMVCRKGEWVALNPLRKCQKRPCGHPGDTP FGTFTLTGGNVFEYGVKAVYTCNEGYQLLGEINYRECDTDGWTNDI PICEVVKCLPVTAPENGKIVSSAMEPDREYHFGQAVRFVCNSGYKIE GDEEMHCSDDGFWSKEKPKCVEISCKSPDVINGSPISQKIIYKENERF QYKCNMGYEYSERGDAVCTESGWRPLPSCEEKSCDNPYIPNGDYSP LRIKHRTGDEITYQCRNGFYPATRGNTAKCTSTGWIPAPRCTLKPCD YPDIKHGGLYHENMRRPYFPVAVGKYYSYYCDEHFETPSGSYWDH IHCTQDGWSPAVPCLRKCYFPYLENGYNQNYGRKFVQGKSIDVAC HPGYALPKAQTTVTCMENGWSPTPRCIRVKTCSKSSIDIENGFISESQ YTYALKEKAKYQCKLGYVTADGETSGSITCGKDGWSAQPTCIKSC DIPVFMNARTKNDFTWFKLNDTLDYECHDGYESNTGSTTGSIVCGY NGWSDLPICYERECELPKIDVHLVPDRKKDQYKVGEVLKFSCKPGF TIVGPNSVQCYHFGLSPDLPICKEQVQSCGPPPELLNGNVKEKTKEE YGHSEVVEYYCNPRFLMKGPNKIQCVDGEWTTLPVCIVEESTCGDI PELEHGWAQLSSPPYYYGDSVEFNCSESFTMIGHRSITCIHGVWTQL PQCVAIDKLKKCKSSNLIILEEHLKNKKEFDHNSNIRYRCRGKEGWI HTVCINGRWDPEVNCSMAQIQLCPPPPQIPNSHNMTTTLNYRDGEK VSVLCQENYLIQEGEEITCKDGRWQSIPLCVEKIPCSQPPQIEHGTINS SRSSQESYAHGTKLSYTCEGGFRISEENETTCYMGKWSSPPQCEGLP CKSPPEISHGVVAHMSDSYQYGEEVTYKCFEGFGIDGPAIAKCLGEK WSHPPSCIKTDCLSLPSFENAIPMGEKKDVYKAGEQVTYTCATYYK MDGASNVTCINSRWTGRPTCRDTSCVNPPTVQNAYIVSRQMSKYPS GERVRYQCRSP YEMFGDEEVMCLNGNWTEPPQCKDSTGKCGPPPPIDNGDITSFPLSV YAPASSVEYQCQNLYQLEGNKRITCRNGQWSEPPKCLHPCVISREIM ENYNIALRWTAKQKLYSRTGESVEFVCKRGYRLSSRSHTLRTTCWD GKLEYPTCAKR 395 MEPRPTAPSSGAPGLAGVGETPSAAALAAARVELPGTAVPSVPEDA SLC12A2 APASRDGGGVRDEGPAAAGDGLGRPLGPTPSQSRFQVDLVSENAG RAAAAAAAAAAAAAAAGAGAGAKQTPADGEASGESEPAKGSEEA KGRFRVNFVDPAASSSAEDSLSDAAGVGVDGPNVSFQNGGDTVLSE GSSLHSGGGGGSGHHQHYYYDTHTNTYYLRTFGHNTMDAVPRIDH YRHTAAQLGEKLLRPSLAELHDELEKEPFEDGFANGEESTPTRDAV VTYTAESKGVVKFGWIKGVLVRCMLNIWGVMLFIRLSWIVGQAGI GLSVLVIMMATVVTTITGLSTSAIATNGFVRGGGAYYLISRSLGPEF GGAIGLIFAFANAVAVAMYVVGFAETVVELLKEHSILMIDEINDIRII GAITVVILLGISVAGMEWEAKAQIVLLVILLLAIGDFVIGTFIPLESKK PKGFFGYKSEIFNENFGPDFREEETFFSVFAIFFPAATGILAGANISGD LADPQSAIPKGTLLAILITTLVYVGIAVSV GSCVVRDATGNVNDTIVTELTNCTSAACKLNFDFSSCESSPCSYGL MNNFQVMSMVSGFTPLISAGIFSATLSSALASLVSAPKIFQALCKDNI YPAFQMFAKGYGKNNEPLRGYILTFLIALGFILIAELNVIAPIISNFFL ASYALINFSVFHASLAKSPGWRPAFKYYNMWISLLGAILCCIVMFVI NWWAALLTYVIVLGLYIYVTYKKPDVNWGSSTQALTYLNALQHSI RLSGVEDHVKNFRPQCLVMTGAPNSRPALLHLVHDFTKNVGLMIC GHVHMGPRRQAMKEMSIDQAKYQRWLIKNKMKAFYAPVHADDL REGAQYLMQAAGLGRMKPNTLVLGFKKDWLQADMRDVDMYINL FHDAFDIQYGVVVIRLKEGLDISHLQGQEELLSSQEKSPGTKDVVVS VEYSKKSDLDTSKPLSEKPITHKVEEEDGKTATQPLLKKESKGPIVPL NVADQKLLEASTQFQKKQGKNTIDVWWLFDDGGLTLLIPYLLTTK KKWKDCKIRVFIGGKINRIDHDRRAMATLLSKFRIDFSDIMVLGDIN TKPKKENIIAFEEIIEPYRLHEDDKEQDIADKMKEDEPWRITDNELEL YKTKTYRQIRLNELLKEHSSTANIIVMSLPVARKGAVSSALYMAWL EALSKDLPPILLVRGNHQSVLTFYS 396 MAASKKAVLGPLVGAVDQGTSSTRFLVFNSKTAELLSHHQVEIKQE GK FPREGWVEQDPKEILHSVYECIEKTCEKLGQLNIDISNIKAIGVSNQR ETTVVWDKITGEPLYNAVVWLDLRTQSTVESLSKRIPGNNNFVKSK TGLPLSTYFSAVKLRWLLDNVRKVQKAVEEKRALFGTIDSWLIWSL TGGVNGGVHCTDVTNASRTMLFNIHSLEWDKQLCEFFGIPMEILPN VRSSSEIYGLMKISHSVKAGALEGVPISGCLGDQSAALVGQMCFQIG QAKNTYGTGCFLLCNTGHKCVFSDHGLLTTVAYKLGRDKPVYYAL EGSVAIAGAVIRWLRDNLGIIKTSEEIEKLAKEVGTSYGCYFVPAFSG LYAPYWEPSARGIICGLTQFTNKCHIAFAALEAVCFQTREILDAMNR DCGIPLSHLQVDGGMTSNKILMQLQADILYIPVVKPSMPETTALGAA MAAGAAEGVGVWSLEPEDLSAVTMERFEPQINAEESEIRYSTWKK AVMKSMGWVTTQSPESGDPSIFCSLPLGF FIVSSMVMLIGARYISGIP 397 MDVGSKEVLMESPPDYSAAPRGRFGIPCCPVHLKRLLIVVVVVVLIV SFTPC VVIVGALLMGLHMSQKHTEMVLEMSIGAPEAQQRLALSEHLVTTA TFSIGSTGLVVYDYQQLLIAYKPAPGTCCYIMKIAPESIPSLEALNRK VHNFQMECSLQAKPAVPTSKLGQAEGRDAGSAPSGGDPAFLGMAV NTLCGEVPLYYI 398 MEPGRRGAAALLALLCVACALRAGRAQYERYSFRSFPRDELMPLES CRTAP AYRHALDKYSGEHWAESVGYLEISLRLHRLLRDSEAFCHRNCSAAP QPEPAAGLASYPELRLFGGLLRRAHCLKRCKQGLPAFRQSQPSREV LADFQRREPYKFLQFAYFKANNLPKAIAAAHTFLLKHPDDEMMKR NMAYYKSLPGAEDYIKDLETKSYESLFIRAVRAYNGENWRTSITDM ELALPDFFKAFYECLAACEGSREIKDFKDFYLSIADHYVEVLECKIQ CEENLTPVIGGYPVEKFVATMYHY LQFAYYKLNDLKNAAPCAVSYLLFDQNDKVMQQNLVYYQYHRDT WGLSDEHFQPRPEAVQFFNVTTLQKELYDFAKENIMDDDEGEVVE YVDDLLELEETS 399 MAVRALKLLTTLLAVVAAASQAEVESEAGWGMVTPDLLFAEGTA P3H1 AYARGDWPGVVLSMERALRSRAALRALRLRCRTQCAADFPWELDP DWSPSPAQASGAAALRDLSFFGGLLRRAACLRRCLGPPAAHSLSEE MELEFRKRSPYNYLQVAYFKINKLEKAVAAAHTFFVGNPEHMEMQ QNLDYYQTMSGVKEADFKDLETQPHMQEFRLGVRLYSEEQPQEAV PHLEAALQEYFVAYEECRALCEGPYDYDGYNYLEYNADLFQAITD HYIQVLNCKQNCVTELASHPSREKPFEDFLPSHYNYLQFAYYNIGN YTQAVECAKTYLLFFPNDEVMNQNLAYYAAMLGEEHTRSIGPRES AKEYRQRSLLEKELLFFAYDVFGIPFVDPDSWTPEEVIPKRLQEKQK SERETAVRISQEIGNLMKEIETLVEEKTKESLDVSRLTREGGPLLYEG ISLTMNSKLLNGSQRVVMDGVISDHECQELQRLTNVAATSGDGYR GQTSPHTPNEKFYGVTVFKALKLGQEGKVPLQSAHLYYNVTEKVR RIMESYFRLDTPLYFSYSHLVCRTAIEEVQAERKDDSHPVHVDNCIL NAETLVCVKEPPAYTFRDYSAILYLNGDFDGGNFYFTELDAKTVTA EVQPQCGRAVGFSSGTENPHGVKAVTRGQRCAIALWFTLDPRHSER DRVQADDLVKMLFSPEEMDLSQEQPLDAQQGPPEPAQESLSGSESK PKDEL 400 MTLRLLVAALCAGILAEAPRVRAQHRERVTCTRLYAADIVFLLDGS COL7A1 SSIGRSNFREVRSFLEGLVLPFSGAASAQGVRFATVQYSDDPRTEFG LDALGSGGDVIRAIRELSYKGGNTRTGAAILHVADHVFLPQLARPG VPKVCILITDGKSQDLVDTAAQRLKGQGVKLFAVGIKNADPEELKR VASQPTSDFFFFVNDFSILRTLLPLVSRRVCTTAGGVPVTRPPDDSTS APRDLVLSEPSSQSLRVQWTAASGPVTGYKVQYTPLTGLGQPLPSE RQEVNVPAGETSVRLRGLRPLTEYQVTVIALYANSIGEAVSGTARTT ALEGPELTIQNTTAHSLLVAWRSVPGATGYRVTWRVLSGGPTQQQE LGPGQGSVLLRDLEPGTDYEVTVSTLFGRSVGPATSLMARTDASVE QTLRPVILGPTSILLSWNLVPEARGYRLEWRRETGLEPPQKVVLPSD VTRYQLDGLQPGTEYRLTLYTLLEGHEVATPATVVPTGPELPVSPVT DLQATELPGQRVRVSWSPVPGATQYRII VRSTQGVERTLVLPGSQTAFDLDDVQAGLSYTVRVSARVGPREGSA SVLTVRREPETPLAVPGLRVVVSDATRVRVAWGPVPGASGFRISWS TGSGPESSQTLPPDSTATDITGLQPGTTYQVAVSVLRGREEGPAAVI VARTDPLGPVRTVHVTQASSSSVTITWTRVPGATGYRVSWHSAHGP EKSQLVSGEATVAELDGLEPDTEYTVHVRAHVAGVDGPPASVVVR TAPEPVGRVSRLQILNASSDVLRITWVGVTGATAYRLAWGRSEGGP MRHQILPGNTDSAEIRGLEGGVSY SVRVTALVGDREGTPVSIVVTTPPEAPPALGTLHVVQRGEHSLRLR WEPVPRAQGFLLHWQPEGGQEQSRVLGPELSSYHLDGLEPATQYR VRLSVLGPAGEGPSAEVTARTESPRVPSIELRVVDTSIDSVTLAWTP VSRASSYILSWRPLRGPGQEVPGSPQTLPGISSSQRVTGLEPGVSYIFS LTPVLDGVRGPEASVTQTPVCPRGLADVVFLPHATQDNAHRAEATR RVLERLVLALGPLGPQAVQVGLLSYSHRPSPLFPLNGSHDLGIILQRI RDMPYMDPSGNNLGTAVVTAHRYMLAPDAPGRRQHVPGVMVLLV DEPLRGDIFSPIREAQASGLNVVMLGMAGADPEQLRRLAPGMDSVQ TFFAVDDGPSLDQAVSGLATALCQASFTTQPRPEPCPVYCPKGQKG EPGEMGLRGQVGPPGDPGLPGRTGAPGPQGPPGSATAKGERGFPGA DGRPGSPGRAGNPGTPGAPGLKGSPGLPGPRGDPGERGPRGPKGEP GAPGQVIGGEGPGLPGRKGDPGPSGPPGPRGPLGDPGPRGPPGLPGT AMKGDKGDRGERGPPGPGEGGIAPGEPGLPGLPGSPGPQGPVGPPG KKGEKGDSEDGAPGLPGQPGSPGEQGPRGPPGAIGPKGDRGFPGPL GEAGEKGERGPPGPAGSRGLPGVAGRPGAKGPEGPPGPTGRQGEKG EPGRPGDPAVVGPAVAGPKGEKGDVGPAGPRGATGVQGERGPPGL VLPGDPGPKGDPGDRGPIGLTGRAGPPGDSGPPGEKGDPGRPGPPGP VGPRGRDGEVGEKGDEGPPGDPGLPGKAGERGLRGAPGVRGPVGE KGDQGDPGEDGRNGSPGSSGPKGDRGEPGPPGPPGRLVDTGPGARE KGEPGDRGQEGPRGPKGDPGLPGAPGERGIEGFRGPPGPQGDPGVR GPAGEKGDRGPPGLDGRSGLDGKPGAAGPSGPNGAAGKAGDPGRD GLPGLRGEQGLPGPSGPPGLPGKPGEDGKPGLNGKNGEPGDPGEDG RKGEKGDSGASGREGRDGPKGERGAPGILGPQGPPGLPGPVGPPGQ GFPGVPGGTGPKGDRGETGSKGEQGLPGERGLRGEPGSVPNVDRLL ETAGIKASALREIVETWDESSGSFLPVPERRRGPKGDSGEQGPPGKE GPIGFPGERGLKGDRGDPGPQGPPGLALGERGPPGPSGLAGEPGKPG IPGLPGRAGGVGEAGRPGERGERGEKGERGEQGRDGPPGLPGTPGP PGPPGPKVSVDEPGPGLSGEQGPPGLKGAKGEPGSNGDQGPKGDRG VPGIKGDRGEPGPRGQDGNPGLPGERGMAGPEGKPGLQGPRGPPGP VGGHGDPGPPGAPGLAGPAGPQGPSGLKGEPGETGPPGRGLTGPTG AVGLPGPPGPSGLVGPQGSPGLPGQVGETGKPGAPGRDGASGKDG DRGSPGVPGSP GLPGPVGPKGEPGPTGAPGQAVVGLPGAKGEKGAPGGLAGDLVGE PGAKGDRGLPGPRGEKGEAGRAGEPGDPGEDGQKGAPGPKGFKGD PGVGVPGSPGPPGPPGVKGDLGLPGLPGAPGVVGFPGQTGPRGEMG QPGPSGERGLAGPPGREGIPGPLGPPGPPGSVGPPGASGLKGDKGDP GVGLPGPRGERGEPGIRGEDGRPGQEGPRGLTGPPGSRGERGEKGD VGSAGLKGDKGDSAVILGPPGPRGAKGDMGERGPRGLDGDKGPRG DNGDPGDKGSKGEPGDKGSAGLPGLRGLLGPQGQPGAAGIPGDPGS PGKDGVPGIRGEKGDVGFMGPRGLKGERGVKGACGLDGEKGDKG EAGPPGRPGLAGHKGEMGEPGVPGQSGAPGKEGLIGPKGDRGFDG QPGPKGDQGEKGERGTPGIGGFPGPSGNDGSAGPPGPPGSVGPRGPE GLQGQKGERGPPGERVVGAPGVPGAPGERGEQGRPGPAGPRGEKG EAALTEDDIRGFVRQEMSQHCACQGQFIASGSRPLPSYAADTAGSQ LHAVPVLRVSHAEEEERVPPEDDEYSEYSEYSVEEYQDPEAPWDSD DPCSLPLDEGSCTAYTLRWYHRAVTGSTEACHPFVYGGCGGNANR FGTREACERRCPPRVVQSQGTGTAQD 401 MSIQENISSLQLRSWVSKSQRDLAKSILIGAPGGPAGYLRRASVAQL PKLR TQELGTAFFQQQQLPAAMADTFLEHLCLLDIDSEPVAARSTSIIATIG PASRSVERLKEMIKAGMNIARLNFSHGSHEYHAESIANVREAVESFA GSPLSYRPVAIALDTKGPEIRTGILQGGPESEVELVKGSQVLVTVDPA FRTRGNANTVWVDYPNIVRVVPVGGRIYIDDGLISLVVQKIGPEGLV TQVENGGVLGSRKGVNLPGAQVDLPGLSEQDVRDLRFGVEHGVDI VFASFVRKASDVAAVRAALGPEGHGIKIISKIENHEGVKRFDEILEVS DGIMVARGDLGIEIPAEKVFLAQKMMIGRCNLAGKPVVCATQMLES MITKPRPTRAETSDVANAVLDGADCIMLSGETAKGNFPVEAVKMQ HAIAREAEAAVYHRQLFEELRRAAPLSRDPTEVTAIGAVEAAFKCC AAAIIVLTTTGRSAQLLSRYRPRAAVIAVTRSAQAARQVHLCRGVFP LLYREPPEAIWADDVDRRVQFGIESG KLRGFLRVGDLVIVVTGWRPGSGYTNIMRVLSIS 402 MSSPVKRQRMESALDQLKQFTTVVADTGDFHAIDEYKPQDATTNP TALDO1 SLILAAAQMPAYQELVEEAIAYGRKLGGSQEDQIKNAIDKLFVLFGA EILKKIPGRVSTEVDARLSFDKDAMVARARRLIELYKEAGISKDRILI KLSSTWEGIQAGKELEEQHGIHCNMTLLFSFAQAVACAEAGVTLISP FVGRILDWHVANTDKKSYEPLEDPGVKSVTKIYNYYKKFSYKTIVM GASFRNTGEIKALAGCDFLTISPKLLGELLQDNAKLVPVLSAKAAQA SDLEKIHLDEKSFRWLHNEDQMAVEKLSDGIRKFAADAVKLERML TERMFNAENGK 403 MRLAVGALLVCAVLGLCLAVPDKTVRWCAVSEHEATKCQSFRDH TF MKSVIPSDGPSVACVKKASYLDCIRAIAANEADAVTLDAGLVYDAY LAPNNLKPVVAEFYGSKEDPQTFYYAVAVVKKDSGFQMNQLRGK KSCHTGLGRSAGWNIPIGLLYCDLPEPRKPLEKAVANFFSGSCAPCA DGTDFPQLCQLCPGCGCSTLNQYFGYSGAFKCLKDGAGDVAFVKH STIFENLANKADRDQYELLCLDNTRKPVDEYKDCHLAQVPSHTVVA RSMGGKEDLIWELLNQAQEHFGKDKSKEFQLFSSPHGKDLLFKDSA HGFLKVPPRMDAKMYLGYEYVTAIRNLREGTCPEAPTDECKP VKWCALSHHERLKCDEWSVNSVGKIECVSAETTEDCIAKIMNGEA DAMSLDGGFVYIAGKCGLVPVLAENYNKSDNCEDTPEAGYFAIAV VKKSASDLTWDNLKGKKSCHTAVGRTAGWNIPMGLLYNKINHCRF DEFFSEGCAPGSKKDSSLCKLCMGSGLNLCEPNNKEGYYGYTGAFR CLVEKGDVAFVKHQTVPQNTGGKNPDPWAKNLNEKDYELLCLDG TRKPVEEYANCHLARAPNHAVVTRKDKEACVHKILRQQQHLFGSN VTDCSGNFCLFRSETKDLLFRDDTVCLAKLHDRNTYEKYLGEEYVK AVGNLRKCSTSSLLEACTFRRP 404 MAPPQVLAFGLLLAAATATFAAAQEECVCENYKLAVNCFVNNNRQ EPCAM CQCTSVGAQNTVICSKLAAKCLVMKAEMNGSKLGRRAKPEGALQN NDGLYDPDCDESGLFKAKQCNGTSMCWCVNTAGVRRTDKDTEITC SERVRTYWIIIELKHKAREKPYDSKSLRTALQKEITTRYQLDPKFITSI LYENNVITIDLVQNSSQKTQNDVDIADVAYYFEKDVKGESLFHSKK MDLTVNGEQLDLDPGQTLIYYVDEKAPEFSMQGLKAGVIAVIVVVV IAVVAGIVVLVISRKKRMAKYEKA EIKEMGEMHRELNA 405 MPRRAENWDEAEVGAEEAGVEEYGPEEDGGEESGAEESGPEESGPE VHL ELGAEEEMEAGRPRPVLRSVNSREPSQVIFCNRSPRVVLPVWLNFD GEPQPYPTLPPGTGRRIHSYRGHLWLFRDAGTHDGLLVNQTELFVPS LNVDGQPIFANITLPVYTLKERCLQVVRSLVKPENYRRLDIVRSLYE DLEDHPNVQKDLERLTQERIAHQRMGD 406 MKRVLVLLLAVAFGHALERGRDYEKNKVCKEFSHLGKEDFTSLSL GC VLYSRKFPSGTFEQVSQLVKEVVSLTEACCAEGADPDCYDTRTSAL SAKSCESNSPFPVHPGTAECCTKEGLERKLCMAALKHQPQEFPTYV EPTNDEICEAFRKDPKEYANQFMWEYSTNYGQAPLSLLVSYTKSYL SMVGSCCTSASPTVCFLKERLQLKHLSLLTTLSNRVCSQYAAYGEK KSRLSNLIKLAQKVPTADLEDVLPLAEDITNILSKCCESASEDCMAK ELPEHTVKLCDNLSTKNSKFEDCCQEKTAMDVFVCTYFMPAAQLPE LPDVELPTNKDVCDPGNTKVMDKYTFELSRRTHLPEVFLSKVLEPT LKSLGECCDVEDSTTCFNAKGPLLKKELSSFIDKGQELCADYSENTF TEYKKKLAERLKAKLPDATPTELAKLVNKHSDFASNCCSINSPPLYC DSEIDAELKNIL 407 MPSSVSWGILLLAGLCCLVPVSLAEDPQGDAAQKTDTSHHDQDHPT SERPINA1 FNKITPNLAEFAFSLYRQLAHQSNSTNIFFSPVSIATAFAMLSLGTKA DTHDEILEGLNFNLTEIPEAQIHEGFQELLRTLNQPDSQLQLTTGNGL FLSEGLKLVDKFLEDVKKLYHSEAFTVNFGDTEEAKKQINDYVEKG TQGKIVDLVKELDRDTVFALVNYIFFKGKWERPFEVKDTEEEDFHV DQVTTVKVPMMKRLGMFNIQHCKKLSSWVLLMKYLGNATAIFFLP DEGKLQHLENELTHDIITKFLENEDRRSASLHLPKLSITGTYDLKSVL GQLGITKVFSNGADLSGVTEEAPLKLSKAVHKAVLTIDEKGTEAAG AMFLEAIPMSIPPEVKFNKPFVFLMIEQNTKSPLFMGKVVNPTQK 408 MAAPAEPCAGQGVWNQTEPEPAATSLLSLCFLRTAGVWVPPMYL ABCC6 WVLGPIYLLFIHHHGRGYLRMSPLFKAKMVLGFALIVLCTSSVAVA LWKIQQGTPEAPEFLIHPTVWLTTMSFAVFLIHTERKKGVQSSGVLF GYWLLCFVLPATNAAQQASGAGFQSDPVRHLSTYLCLSLVVAQFV LSCLADQPPFFPEDPQQSNPCPETGAAFPSKATFWWVSGLVWRGYR RPLRPKDLWSLGRENSSEELVSRLEKEWMRNRSAARRHNKAIAFKR KGGSGMKAPETEPFLRQEGSQWRPLL KAIWQVFHSTFLLGTLSLIISDVFRFTVPKLLSLFLEFIGDPKPPAWKG YLLAVLMFLSACLQTLFEQQNMYRLKVLQMRLRSAITGLVYRKVL ALSSGSRKASAVGDVVNLVSVDVQRLTESVLYLNGLWLPLVWIVV CFVYLWQLLGPSALTAIAVFLSLLPLNFFISKKRNHHQEEQMRQKDS RARLTSSILRNSKTIKFHGWEGAFLDRVLGIRGQELGALRTSGLLFS VSLVSFQVSTFLVALVVFAVHTLVAENAMNAEKAFVTLTVLNILNK AQAFLPFSIHSLVQARVSFDRLVTFLCLEEVDPGVVDSSSSGSAAGK DCITIHSATFAWSQESPPCLHRINLTVPQGCLLAVVGPVGAGKSSLLS ALLGELSKVEGFVSIEGAVAYVPQEAWVQNTSVVENVCFGQELDPP WLERVLEACALQPDVDSFPEGIHTSIGEQGMNLSGGQKQRLSLARA VYRKAAVYLLDDPLAALDAHVGQHVFNQVIGPGGLLQGTTRILVT HALHILPQADWIIVLANGAIAEMGSYQELLQRKGALMCLLDQARQP GDRGEGETEPGTSTKDPRGTSAGRRPELRRERSIKSVPEKDRTTSEA QTEVPLDDPDRAGWPAGKDSIQYGRVKATVHLAYLRAVGTPLCLY ALFLFLCQQVASFCRGYWLSLWADDPAVGGQQTQAALRGGIFGLL GCLQAIGLFASMAAVLLGGARASRLLFQRLLWDVVRSPISFFERTPI GHLLNRFSKETDTVDVDIPDKLRSLLMYAFGLLEVSLVVAVATPLA TVAILPLFLLYAGFQSLYVVSSCQLRRLESASYSSVCSHMAETFQGS TVVRAF RTQAPFVAQNNARVDESQRISFPRLVADRWLAANVELLGNGLVFA AATCAVLSKAHLSAGLVGFSVSAALQVTQTLQWVVRNWTDLENSI VSVERMQDYAWTPKEAPWRLPTCAAQPPWPQGGQIEFRDFGLRYR PELPLAVQGVSFKIHAGEKVGIVGRTGAGKSSLASGLLRLQEAAEG GIWIDGVPIAHVGLHTLRSRISIIPQDPILFPGSLRMNLDLLQEHSDEA IWAALETVQLKALVASLPGQLQYKCADRGEDLSVGQKQLLCLARA LLRKTQILILDEATAAVDPGTELQM QAMLGSWFAQCTVLLIAHRLRSVMDCARVLVMDKGQVAESGSPA QLLAQKGLFYRLAQESGLV 409 MQIELSTCFFLCLLRFCFSATRRYYLGAVELSWDYMQSDLGELPVD F8 ARFPPRVPKSFPFNTSVVYKKTLFVEFTDHLFNIAKPRPPWMGLLGP TIQAEVYDTVVITLKNMASHPVSLHAVGVSYWKASEGAEYDDQTS QREKEDDKVFPGGSHTYVWQVLKENGPMASDPLCLTYSYLSHVDL VKDLNSGLIGALLVCREGSLAKEKTQTLHKFILLFAVFDEGKSWHSE TKNSLMQDRDAASARAWPKMHTVNGYVNRSLPGLIGCHRKSVYW HVIGMGTTPEVHSIFLEGHTFLVRNHRQASLEISPITFLTAQTLLMDL GQFLLFCHISSHQHDGMEAYVKVDSCPEPQLRMKNNEEAEDYDD DLTDSEMDVVRFDDDNSPSFIQIRSVAKKHPKTWVHYIAAEEEDWD YAPLVLAPDDRSYKSQYLNNGPQRIGRKYKKVRFMAYTDETFKTR EAIQHESGILGPLLYGEVGDTLLIIFKNQASRPYNIYPHGITDVRPLYS RRLPKGVKHLKDFPILPGEIFKYKWTVTVEDGPTKSDPRCLTRYYSS FVNMERDLASGLIGPLLICYKESVDQRGNQIMSDKRNVILFSVFDEN RSWYLTENIQRFLPNPAGVQLEDPEFQASNIMHSINGYVFDSLQLSV CLHEVAYWYILSIGAQTDFLSVFFSGYTFKHKMVYEDTLTLFPFSGE TVFMSMENPGLWILGCHNSDFRNRGMTALLKVSSCDKNTGDYYED SYEDISAYLLSKNNAIEPRSFSQNSRHPSTRQKQFNATTIPENDIEKTD PWFAHRTPMPKIQNVSSSDLLMLLRQSPTPHGLSLSDLQEAKYETFS DDPS PGAIDSNNSLSEMTHFRPQLHHSGDMVFTPESGLQLRLNEKLGTTA ATELKKLDFKVSSTSNNLISTIPSDNLAAGTDNTSSLGPPSMPVHYDS QLDTTLFGKKSSPLTESGGPLSLSEENNDSKLLESGLMNSQESSWGK NVSSTESGRLFKGKRAHGPALLTKDNALFKVSISLLKTNKTSNNSAT NRKTHIDGPSLLIENSPSVWQNILESDTEFKKVTPLIHDRMLMDKNA TALRLNHMSNKTTSSKNMEMVQQKKEGPIPPDAQNPDMSFFKMLF LPESARWIQRTHGKNSLNSGQGPSPKQLVSLGPEKSVEGQNFLSEKN KVVVGKGEFTKDVGLKEMVFPSSRNLFLTNLDNLHENNTHNQEKK IQEEIEKKETLIQENVVLPQIHTVTGTKNFMKNLFLLSTRQNVEGSYD GAYAPVLQDFRSNDSTNRTKKHTAHFSKKGEEENLEGLGNQTKQI VEKYACTTRISPNTSQQNFVTQRSKRALKQFRLPLEETELEKRIIVDD TSTQWSKNMKHLTPSTLTQIDYNEKE KGAITQSPLSDCLTRSHSIPQANRSPLPIAKVSSFPSIRPIYLTRVLFQD NSSHLPAASYRKKDSGVQESSHFLQGAKKNNLSLAILTLEMTGDQR EVGSLGTSATNSVTYKKVENTVLPKPDLPKTSGKVELLPKVHIYQK DLFPTETSNGSPGHLDLVEGSLLQGTEGAIKWNEANRPGKVPFLRV ATESSAKTPSKLLDPLAWDNHYGTQIPKEEWKSQEKSPEKTAFKKK DTILSLNACESNHAIAAINEGQNKPEIEVTWAKQGRTERLCSQNPPV LKRHQREITRTTLQSDQEEIDYDDTISVEMKKEDFDIYDEDENQSPR SFQKKTRHYFIAAVERLWDYGMSSSPHVLRNRAQSGSVPQFKKVVF QEFTDGSFTQPLYRGELNEHLGLLGPYIRAEVEDNIMVTFRNQASRP YSFYSSLISYEEDQRQGAEPRKNFVKPNETKTYFWKVQHHMAPTKD EFDCKAWAYFSDVDLEKDVHSGLIGPLLVCHTNTLNPAHGRQVTV QEFALFFTIFDETKSWYFTENMERNCRA PCNIQMEDPTFKENYRFHAINGYIMDTLPGLVMAQDQRIRWYLLSM GSNENIHSIHFSGHVFTVRKKEEYKMALYNLYPGVFETVEMLPSKA GIVVRVECLIGEHLHAGMSTLFLVYSNKCQTPLGMASGHIRDFQITAS GQYGQWAPKLARLHYSGSINAWSTKEPFSWIKVDLLAPMIIHGIKT QGARQKFSSLYISQFIIMYSLDGKKWQTYRGNSTGTLMVFFGNVDS SGIKHNIFNPPIIARYIRLHPTHYSIRSTLRMELMGCDLNSCSMPLGM ESKAISDAQITASSYFTNMFATWSPSKARLHLQGRSNAWRPQVNNP KEWLQVDFQKTMKVTGVTTQGVKSLLTSMYVKEFLISSSQDGHQW TLFFQNGKVKVFQGNQDSFTPVVNSLDPPLLTRYLRIHPQSWVHQIA LRMEVLGCEAQDLY 410 MQRVNMIMAESPGLITICLLGYLLSAECTVFLDHENANKILNRPKRY F9 NSGKLEEFVQGNLERECMEEKCSFEEAREVFENTERTTEFWKQYVD GDQCESNPCLNGGSCKDDINSYECWCPFGFEGKNCELDVTCNIKNG RCEQFCKNSADNKVVCSCTEGYRLAENQKSCEPAVPFPCGRVSVSQ TSKLTRAETVFPDVDYVNSTEAETILDNITQSTQSFNDFTRVVGGED AKPGQFPWQVVLNGKVDAFCGGSIVNEKWIVTAAHCVETGVKITV VAGEHNIEETEHTEQKRNVIRII PHHNYNAAINKYNHDIALLELDEPLVLNSYVTPICIADKEYTNIFLKF GSGYVSGWGRVFHKGRSALVLQYLRVPLVDRATCLRSTKFTIYNN MFCAGFHEGGRDSCQGDSGGPHVTEVEGTSFLTGIISWGEECAMKG KYGIYTKVSRYVNwIKEKTKLT 411 MDPPRPALLALLALPALLLLLLAGARAEEEMLENVSLVCPKDATRF ApoB KHLRKYTYNYEAESSSGVPGTADSRSATRINCKVELEVPQLCSFILK TSQCTLKEVYGFNPEGKALLKKTKNSEEFAAAMSRYELKLAIPEGK QVFLYPEKDEPTYILNIKRGIISALLVPPETEEAKQVLFLDTVYGNCS THFTVKTRKGNVATEISTERDLGQCDRFKPIRTGISPLALIKGMTRPL STLIS SSQSCQYTLDAKRKHVAEAICKEQHLFLPFSYKNKYGMVAQVTQT LKLEDTPKINSRFFGEGTKKMGLAFESTKSTSPPKQAEAVLKTLQEL KKLTISEQNIQRANLFNKLVTELRGLSDEAVTSLLPQLIEVSSPITLQA LVQCGQPQCSTHILQWLKRVHANPLLIDVVTYLVALIPEPSAQQLRE IFNMARDQRSRATLYALSHAVNNYHKTNPTGTQELLDIANYLMEQI QDDCTGDEDYTYLILRVIGNMGQTMEQLTPELKSSILKCVQSTKPSL MIQKAAIQALRKMEPKDKD QEVLLQTFLDDASPGDKRLAAYLMLMRSPSQAINKIVQILPWEQNE QVKNFVASHIANILNSEELDIQDLKKLVKEALKESQLPTVMDFRKFS RNYQLYKSVSLPSLDPASAKIEGNLIFDPNNYLPKESMLKTTLTAFG FASADLIEIGLEGKGFEPTLEALFGKQGFFPDSVNKALYWVNGQVP DGVSKVLVDHFGYTKDDKHEQDMVNGIMLSVEKLIKDLKSKEVPE ARAYLRILGEELGFASLHDLQLLGKLLLMGARTLQGIPQMIGEVIRK GSKNDFFLHYIFMENAFELPTGAGLQLQISSSGVIAPGAKAGVKLEV ANMQAELVAKPSVSVEFVTNMGIIIPDFARSGVQMNTNFFHESGLE AHVALKAGKLKFIIPSPKRPVKLLSGGNTLHLVSTTKTEVIPPLIENR QSWSVCKQVFPGLNYCTSGAYSNASSTDSASYYPLTGDTRLELELR PTGEIEQYSVSATYELQREDRALVDTLKFVTQAEGAKQTEATMTFK YNRQSMTLSSEVQIPDFDVDLGTILRVN DESTEGKTSYRLTLDIQNKKITEVALMGHLSCDTKEERKIKGVISIPR LQAEARSEILAHWSPAKLLLQMDSSATAYGSTVSKRVAWHYDEEKI EFEWNTGTNVDTKKMTSNFPVDLSDYPKSLHMYANRLLDHRVPQT DMTFRHVGSKLIVAMSSWLQKASGSLPYTQTLQDHLNSLKEFNLQ NMGLPDFHIPENLFLKSDGRVKYTLNKNSLKIEIPLPFGGKSSRDLK MLETVRTPALHFKSVGFHLPSREFQVPTFTIPKLYQLQVPLLGVLDL STNVYSNLYNWSASYSGGNTST DHFSLRARYHMKADSVVDLLSYNVQGSGETTYDHKNTFTLSYDGS LRHKFLDSNIKFSHVEKLGNNPVSKGLLIFDASSSWGPQMSASVHLD SKKKQHLFVKEVKIDGQFRVSSFYAKGTYGLSCQRDPNTGRLNGES NLRFNSSYLQGTNQITGRYEDGTLSLTSTSDLQSGIIKNTASLKYENY ELTLKSDTNGKYKNFATSNKMDMTFSKQNALLRSEYQADYESLRF FSLLSGSLNSHGLELNADILGTDKINSGAHKATLRIGQDGISTSATTN LKCSLLVLENELNAELGLSGASMKLTTNGRFREHNAKFSLDGKAAL TELSLGSAYQAMILGVDSKNIFNFKVSQEGLKLSNDMMGSYAEMK FDHTNSLNIAGLSLDFSSKLDNIYSSDKFYKQTVNLQLQPYSLVTTL NSDLKYNALDLTNNGKLRLEPLKLHVAGNLKGAYQNNEIKHIYAIS SAALSASYKADTVAKVQGVEFSHRLNTDIAGLASAIDMSTNYNSDS LHFSNVFRSVMAPFTMTIDAHTNGNGKLALWGEHTGQLYSKFLLK AEPLAFTFSHDYKGSTSHHLVSRKSISAALEHKVSALLTPAEQTGTW KLKTQFNNNEYSQDLDAYNTKDKIGVELTGRTLADLTLLDSPIKVPL LLSEPINIIDALEMRDAVEKPQEFTIVAFVKYDKNQDVHSINLPFFET LQEYFERNRQTIIVVLENVQRNLKHINIDQFVRKYRAALGKLPQQA NDYLNSFNWERQVSHAKEKLTALTKKYRITENDIQIALDDAKINFNE KLSQLQTYMIQFDQYIKDSYDLHDLKIAIANIIDEIIEKLKSLDEHYHI RVNLVKTIHDLHLFIENIDFNKSGSSTASWIQNVDTKYQIRIQIQEKL QQLKRHIQNIDIQHLAGKLKQHIEAIDVRVLLDQLGTTISFERINDILE HVKHFVINLIGDFEVAEKINAFRAKVHELIERYEVDQQIQVLMDKLV ELAHQYKLKETIQKLSNVLQQVKIKDYFEKLVGFIDDAVKKLNELSF KTFIEDVNKFLDMLIKKLKSFDYHQFVDETNDKIREVTQRLNGEIQA LELPQKAEALKLFLEETKATVAVYLESLQDTKITLIINWLQEALSSAS LAHMKAKFRETLEDTRDRMYQMDIQQELQRYLSLVGQVYSTLVTY ISDWWTLAAKNLTDFAEQYSIQDWAKRMKALVEQGFTVPEIKTILG TMPAFEVSLQALQKATFQTPDFIVPLTDLRIPSVQINFKDLKNIKIPSR FSTPEFTILNTFHIPSFTIDFVEMKVKIIRTIDQMLNSELQWPVPDIYLR DLKVEDIPLARITLPDFRLPEIAIPEFIIPTLNLNDFQVPDLHIPEFQLPH ISHTIEVPTFGKLYSILKIQSPLFTLDANADIGNGTTSANEAGIAASITA KGESKLEVLNFDFQANAQLSNPKINPLALKESVKFSSKYLRTEHGSE MLFFGNAIEGKSNTVASLHTEKNTLELSNGVIVKINNQLTLDSNTKY FHKLNIPKLDFSSQADLRNEIKTLLKAGHIAWTSSGKGSWKWACPR FSDEGTHESQISFTIEGPLTSFGLSNKINSKHLRVNQNLVYESGSLNFS KLEIQSQVDSQHVGHSVLTAKGMALFGEGKAEFTGRHDAHLNGKV IGTLKNSLFFSAQPFEITASTNNEGNLKVRFPLRLTGKIDFLNNYALF LSPSAQQASWQVSARFNQYKYNQNFSAGNNENIMEAHVGINGE ANLDFLNIPLTIPEMRLPYTIITTPPLKDFSLWEKTGLKEFLKTTKQSF DLSVKAQYKKNKHRHSITNPLAVLCEFISQSIKSFDRHFEKNRNNAL DFVTKSYNETKIKFDKYKAEKSHDELPRTFQIPGYTVPVVNVEVSPF TIEMSAFGYVFPKAVSMPSFSILGSDVRVPSYTLILPSLELPVLHVPR NLKLSLPDFKELCTISHIFIPAMGNITYDFSFKSSVITLNTNAELFNQS DIVAHLLSSSSSVIDALQYKLEGTTRLTRKRGLKLATALSLSNKFVE GSHNSTVSLTTKNMEVSVATTTKAQIPILRMNFKQELNGNTKSKPT VSSSMEFKYDFNSSMLYSTAKGAVDHKLSLESLTSYFSIESSTKGDV KGSVLSREYSGTIASEANTYLNSKSTRSSVKLQGTSKIDDIWNLEVK ENFAGEATLQRIYSLWEHSTKNHLQLEGLFFTNGEHTSKATLELSPW QMSALV QVHASQPSSFHDFPDLGQEVALNANTKNQKIRWKNEVRIHSGSFQS QVELSNDQEKAHLDIAGSLEGHLRFLKNIILPVYDKSLWDFLKLDVT TSIGRRQHLRVSTAFVYTKNPNGYSFSIPVKVLADKFIIPGLKLNDLN SVLVMPTFHVPFTDLQVPSCKLDFREIQIYKKLRTSSFALNLPTLPEV KFPEVDVLTKYSQPEDSLIPFFEITVPESQLTVSQFTLPKSVSDGIAAL DL NAVANKIADFELPTIIVPEQTIEIPSIKFSVPAGIVIPSFQALTARFEVDS PVYNATWSASLKNKADYVETVLDSTCSSTVQFLEYELNVLGTHKIE DGTLASKTKGTFAHRDFSAEYEEDGKYEGLQEWEGKAHLNIKSPAF TDLHLRYQKDKKGISTSAASPAVGTVGMDMDEDDDFSKWNFYYSP QSSPDKKLTIFKTELRVRESDEETQIKVNWEEEAASGLLTSLKDNVP KATGVLYDYVNKYHWEHTGLTLREVSSKLRRNLQNNAEWVYQGA IRQIDDIDVRFQKAASGTTGT YQEWKDKAQNLYQELLTQEGQASFQGLKDNVFDGLVRVTQEFHM KVKHLIDSLIDFLNFPRFQFPGKPGIYTREELCTMFIREVGTVLSQVY SKVHNGSEILFSYFQDLVITLPFELRKHKLIDVISMYRELLKDLSKEA QEVFKAIQSLKTTEVLRNLQDLLQFIFQLIEDNIKQLKEMKFTYLINY IQDEINTIFSDYIPYVFKLLKENLCLNLHKFNEFIQNELQEASQELQQI HQY IMALREEYFDPSIVGWTVKYYELEEKIVSLIKNLLVALKDFHSEYIVS ASNFTSQLSSQVEQFLHRNIQEYLSILTDPDGKGKEKIAELSATAQEII KSQAIATKKIISDYHQQFRYKLQDFSDQLSDYYEKFIAESKRLIDLSI QNYHTFLIYITELLKKLQSTTVMNPYMKLAPGELTIIL 412 MGTVSSRRSWWPLPLLLLLLLLLGPAGARAQEDEDGDYEELVLAL PCSK9 RSEEDGLAEAPEHGTTATFHRCAKDPWRLPGTYVVVLKEETHLSQS ERTARRLQAQAARRGYLTKILHVFHGLLPGFLVKMSGDLLELALKL PHVDYIEEDSSVFAQSIPWNLERITPPRYRADEYQPPDGGSLVEVYL LDTSIQSDHREIEGRVMVTDFENVPEEDGTRFHRQASKCDSHGTHL AGVVSGRDAGVAKGASMRSLRVLNCQGKGTVSGTLIGLEFIRKSQL VQPVGPLVVLLPLAGGYSRVLNAA CQRLARAGVVLVTAAGNFRDDACLYSPASAPEVITVGATNAQDQP VTLGTLGTNFGRCVDLFAPGEDIIGASSDCSTCFVSQSGTSQAAAHV AGIAAMMLSAEPELTLAELRQRLIHFSAKDVINEAWFPEDQRVLTPN LVAALPPSTHGAGWQLFCRTVWSAHSGPTRMATAVARCAPDEELL SCSSFSRSGKRRGERMEAQGGKLVCRAHNAFGGEGVYAIARCCLLP QANCSVHTAPPAEASMGTRVHCHQQGHVLTGCSSHWEVEDLGTH KPPVLRPRGQPNQCVGHREASIHASCCHAPGLECKVKEHGIPAPQE QVTVACEEGWTLTGCSALPGTSHVLGAYAVDNTCVVRSRDVSTTG STSEGAVTAVAICCRSRHLAQASQELQ 413 MDALKSAGRALIRSPSLAKQSWGGGGRHRKLPENWTDTRETLLEG LDLRAP1 MLFSLKYLGMTLVEQPKGEELSAAAIKRIVATAKASGKKLQKVTLK VSPRGIILTDNLTNQLIENVSIYRISYCTADKMHDKVFAYIAQSQHNQ SLECHAFLCTKRKMAQAVTLTVAQAFKVAFEFWQVSKEEKEKRDK ASQEGGDVLGARQDCTPSLKSLVATGNLLDLEETAKAPLSTVSANT TNMDEVPRPQALSGSSVVWELDDGLDEAFSRLAQSRTNPQVLDTG LTAQDMHYAQCLSPVDWDKPDSSGTEQDDLFSF 414 MGDLSSLTPGGSMGLQVNRGSQSSLEGAPATAPEPHSLGILHASYSV ABCG5 SHRVRPWWDITSCRQQWTRQILKDVSLYVESGQIMCILGSSGSGKT TLLDAMSGRLGRAGTFLGEVYVNGRALRREQFQDCFSYVLQSDTL LSSLTVRETLHYTALLAIRRGNPGSFQKKVEAVMAELSLSHVADRLI GNYSLGGISTGERRRVSIAAQLLQDPKVMLFDEPTTGLDCMTANQI VVLLVELARRNRIVVLTIHQPRSELFQLFDKIAILSFGELIFCGTPAEM LDFFNDCGYPCPEHSNPFDFYMDLTSVDTQSKEREIETSKRVQMIES AYKKSAICHKTLKNIERMKHLKTLPMVPFKTKDSPGVFSKLGVLLR RVTRNLVRNKLAVITRLLQNLIMGLFLLFFVLRVRSNVLKGAIQDRV GLLYQFVGATPYTGMLNAVNLFPVLRAVSDQESQDGLYQKWQMM LAYALHVLPFSVVATMIFSSVCYWTLGLHPEVARFGYFSAALLAPH LIGEFLTLVLLGIVQNPNIVNSVVALLSIAGVLVGSGFLRNIQEMPIPF KIISYFTFQKYCSEILVVNEFYGLNFTCGSSNVSVTTNPMCAFTQGIQ FIEKTCPGATSRFTMNFLILYSFIPALVILGIVVFKIRDHLISR 415 MAGKAAEERGLPKGATPQDTSGLQDRLFSSESDNSLYFTYSGQPNT ABCG8 LEVRDLNYQVDLASQVPWFEQLAQFKMPWTSPSCQNSCELGIQNLS FKVRSGQMLAIIGSSGCGRASLLDVITGRGHGGKIKSGQIWINGQPSS PQLVRKCVAHVRQHNQLLPNLTVRETLAFIAQMRLPRTFSQAQRDK RVEDVIAELRLRQCADTRVGNMYVRGLSGGERRRVSIGVQLLWNP GILILDEPTSGLDSFTAHNLVKTLSRLAKGNRLVLISLHQPRSDIFRLF DLVLLMTSGTPIYLGAAQHMVQYFTAIGYPCPRYSNPADFYVDLTSI DRRSREQELATREKAQSLAALFLEKVRDLDDFLWKAETKDLDEDT CVESSVTPLDTNCLPSPTKMPGAVQQFTTLIRRQISNDFRDLPTLLIH GAEACLMSMTIGFLYFGHGSIQLSFMDTAALLFMIGALIPFNVILDVI SKCYSERAMLYYELEDGLYTTGPYFFAKILGELPEHCAYIIIYGMPT YWLANLRPGLQPFLLHFLLVWLVVFCCRIMALAAAALLPTFHMASF FSNALYNSFYLAGGFMINLSSLWTVPAWISKVSFLRWCFEGLMKIQ FSRRTYKMPLGNLTIAVSGDKILSVMELDSYPLYAIYLIVIGLSGGFM VLYYVSLRFIKQKPSQDW 416 MGPPGSPWQWVTLLLGLLLPPAAPFWLLNVLFPPHTTPKAELSNHT LCAT RPVILVPGCLGNQLEAKLDKPDVVNWMCYRKTEDFFTIWLDLNMF LPLGVDCWIDNTRVVYNRSSGLVSNAPGVQIRVPGFGKTYSVEYLD SSKLAGYLHTLVQNLVNNGYVRDETVRAAPYDWRLEPGQQEEYY RKLAGLVEEMHAAYGKPVFLIGHSLGCLHLLYFLLRQPQAWKDRFI DGFISLGAPWGGSIKPMLVLASGDNQGIPIMSSIKLKEEQRITTTSPW MFPSRMAWPEDHVFISTPSFNYTGR DFQRFFADLHFEEGWYMWLQSRDLLAGLPAPGVEVYCLYGVGLPT PRTYIYDHGFPYTDPVGVLYEDGDDTVATRSTELCGLWQGRQPQPV HLLPLHGIQHLNMVFSNLTLEHINAILLGAYRQGPPASPTASPEPPPP E 417 MKIATVSVLLPLALCLIQDAASKNEDQEMCHEFQAFMKNGKLFCPQ SPINK5 DKKFFQSLDGIMFINKCATCKMILEKEAKSQKRARHLARAPKATAP TELNCDDFKKGERDGDFICPDYYEAVCGTDGKTYDNRCALCAENA KTGSQIGVKSEGECKSSNPEQDVCSAFRPFVRDGRLGCTRENDPVL GPDGKTHGNKCAMCAELFLKEAENAKREGETRIRRNAEKDFCKEY EKQVRNGRLFCTRESDPVRGPDGRMHGNKCALCAEIFKQRFSEENS KTDQNLGKAEEKTKVKREIVKLCSQYQNQAKNGILFCTRENDPIRG PDGKMHGNLCSMCQAYFQAENEEKKKAEARARNKRESGKA TSYAELCSEYRKLVRNGKLACTRENDPIQGPDGKVHGNTCSMCEVF FQAEEEEKKKKEGKSRNKRQSKSTASFEELCSEYRKSRKNGRLFCT RENDPIQGPDGKMHGNTCSMCEAFFQQEERARAKAKREAAKEICSE FRDQVRNGTLICTREHNPVRGPDGKMHGNKCAMCASVFKLEEEEK KNDKEEKGKVEAEKVKREAVQELCSEYRHYVRNGRLPCTRENDPI EGLDGKIHGNTCSMCEAFFQQEAKEKERAEPRAKVKREAEKETCDE FRRLLQNGKLFCTRENDPVRGPDGKTHGNKCAMCKAVFQKENEER KRKEEEDQRNAAGHGSSGGGGGNTQDECAEYREQMKNGRLS CTRESDPVRDADGKSYNNQCTMCKAKLEREAERKNEYSRSRSNGT GSESGKDTCDEFRSQMKNGKLICTRESDPVRGPDGKTHGNKCTMC KEKLEREAAEKKKKEDEDRSNTGERSNTGERSNDKEDLCREFRSM QRNGKLICTRENNPVRGPYGKMHINKCAMCQSIFDREANERKKKD EEKSSSKPSNNAKDECSEFRNYIRNNELICPRENDPVHGADGKFYTN KCYMCRAVFLTEALERAKLQEKPSHVRASQEEDSPDSFSSLDSEMC KDYRVLPRIGYLCPKDLKPVCGDDGQTYNNPCMLCHENLIRQTNTH IRSTGKCEESSTPGTTAASMPPSDE 418 MEKNGNNRKLRVCVATCNRADYSKLAPIMFGIKTEPEFFELDVVVL GNE GSHLIDDYGNTYRMIEQDDFDINTRLHTIVRGEDEAAMVESVGLAL VKLPDVLNRLKPDIMIVHGDRFDALALATSAALMNIRILHIEGGEVS GTIDDSIRHAITKLAHYHVCCTRSAEQHLISMCEDHDRILLAGCPSY DKLLSAKNKDYMSIIRMWLGDDVKSKDYIVALQHPVTTDIKHSIKM FELTLDALISFNKRTLVLFPNIDAGSKEMVRVMRKKGIEHHPNFRAV KHVPFDQFIQLVAHAGCMIGNSSCGVREVGAFGTPVINLGTRQIGRE TGENVLHVRDADTQDKILQALHLQFGKQYPCSKIYGDGNAVPRILK FLKSIDLQEPLQKKFCFPPVKENISQDIDHILETLSALAVDLGGTNLR VAIVSMKGEIVKKYTQFNPKTYEERINLILQMCVEAAAEAVKLNCRI LGVGISTGGRVNPREGIVLHSTKLIQEWNSVDLRTPLSDTLHLPVWV DNDGNCAALAERKFGQGKGLENFVTL ITGTGIGGGIIHQHELIHGSSFCAAELGHLVVSLDGPDCSCGSHGCIE AYASGMALQREAKKLHDEDLLLVEGMSVPKDEAVGALHLIQAAKL GNAKAQSILRTAGTALGLGVVNILHTMNPSLVILSGVLASHYIHIVK DVIRQQALSSVQDVDVVVSDLVDPALLGAASMVLDYTTRRIY 419 DIQMTQTTSSLSASLGDRVTISCRASQDISKYLNWYQQKPDGTVKLL Anti-CD19 scFv IYHTSRLHSGVPSRFSGSGSGTDYSLTISNLEQEDIATYFCQQGNTLP (FMC63) YTFGGGTKLEITGSTSGSGKPGSGEGSTKGEVKLQESGPGLVAPSQS LSVTCTVSGVSLPDYGVSWIRQPPRKGLEWLGVIWGSETTYYNSAL KSRLTIIKDNSKSQVFLKMNSLQTDDTAIYYCAKHYYYGGSYAMD YWGQGTSVTVSS 420 DIQMTQTTSSLSASLGDRVTISCRASQDISKYLNWYQQKPDGTVKLL Anti-CD19 scFv IYHTSRLHSGVPSRFSGSGSGTDYSLTISNLEQEDIATYFCQQGNTLP (FMC63) YTFGGGTKLEITGGGGSGGGGSGGGGSEVKLQESGPGLVAPSQSLS VTCTVSGVSLPDYGVSWIRQPPRKGLEWLGVIVVGSETTYYNSALKS RLTIIKDNSKSQVFLKMNSLQTDDTAIYYCAKHYYYGGSYAMDYW GQGTSVTVSS 421 ESKYGPPCPPCP IgG4 Hinge 422 TTTPAPRPPTPAPTIASQPLSLRPE CD8 Hinge 423 IEVMYPPPYLDNEKSNGTIIHVKGKHLCPSPLFPGPSKP CD28 424 ACRPAAGGAVHTRGLDFACDIYIWAPLAGTCGVLLLSLVITLYC CD8 425 FWVLVVVGGVLACYSLLVTVAFIIFWV CD28 426 FWVLVVVGGVLACYSLLVTVAFIIFWV CD28 427 RSKRSRLLHSDYMNMTPRRPGPTRKHYQPYAPPRDFAAYRS CD28 428 KRGRKKLLYIFKQPFMRPVQTTQEEDGCSCRFPEEEEGGCEL 4-1BB 429 RVKFSRSADAPAYQQGQNQLYNELNLGRREEYDVLDKRRGRDPEM CD3zeta GGKPRRKNPQEGLYNELQKDKMAEAYSEIGMKGERRRGKGHDGL YQGLSTATKDTYDALHMQALPPR 430 RVKFSRSADAPAYKQGQNQLYNELNLGRREEYDVLDKRRGRDPEM CD3zeta GGKPRRKNPQEGLYNELQKDKMAEAYSEIGMKGERRRGKGHDGL YQGLSTATKDTYDALHMQALPPR 

1. A targeted lipid particle, comprising: (a) a lipid bilayer enclosing a lumen, (b) a henipavirus F protein molecule or biologically active portion thereof; and (c) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) single domain antibody (sdAb) variable domain, wherein the sdAb variable domain is attached to the C-terminus of the G protein or the biologically active portion thereof and/or wherein the sdAb is attached to the G protein or the biologically active portion thereof via a peptide linker, wherein the sdAb binds to a cell surface molecule of a target cell, wherein the F protein molecule or the biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer.
 2. The targeted lipid particle of claim 1, wherein the cell surface molecule is a protein, glycan, lipid or low molecular weight molecule.
 3. The targeted lipid particle of claim 1, wherein the target cell is selected from the group consisting of tumor-infiltrating lymphocytes, T cells, neoplastic or tumor cells, virus-infected cells, stem cells, central nervous system (CNS) cells, hematopoeietic stem cells (HSCs), liver cells and fully differentiated cells.
 4. The targeted lipid particle of claim 1, wherein the target cell is selected from the group consisting of a CD3+ T cell, a CD4+ T cell, a CD8+ T cell, a hepatocyte, a haematopoietic stem cell, a CD34+ haematopoietic stem cell, a CD105+ haematopoietic stem cell, a CD117+ haematopoietic stem cell, a CD105+ endothelial cell, a B cell, a CD20+ B cell, a CD19+ B cell, a cancer cell, a CD133+ cancer cell, an EpCAM+ cancer cell, a CD19+ cancer cell, a Her2/Neu+ cancer cell, a GluA2+ neuron, a GluA4+ neuron, a NKG2D+ natural killer cell, a SLC1A3+ astrocyte, a SLC7A10+ adipocyte, and a CD30+ lung epithelial cell.
 5. The targeted lipid particle of claim 1, wherein the single domain antibody binds to an antigen or portion thereof present on a hepatocyte.
 6. The targeted lipid particle of claim 1, wherein the cell surface molecule or antigen is selected from the group consisting of ASGR1, ASGR2 and TM4SF.
 7. The targeted lipid particle of claim 1, wherein the single domain antibody binds to an antigen or portion thereof present on a T cell.
 8. The targeted lipid particle of claim 1, wherein the cell surface molecule or antigen is CD8 or CD4.
 9. The targeted lipid particle of claim 1, wherein the cell surface molecule or antigen is low density lipoprotein receptor (LDL-R).
 10. A targeted lipid particle, comprising: (a) a lipid bilayer enclosing a lumen, (b) a henipavirus F protein molecule or biologically active portion thereof; and (c) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof, and wherein the binding domain binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, TM4SF5, CD8, CD4 and low density lipoprotein receptor (LDL-R), wherein the F protein molecule or the biologically active portion thereof and the targeted envelope protein are embedded in the lipid bilayer. 11-12. (canceled)
 13. The targeted lipid particle of claim 1, wherein the lipid particle is a lentiviral vector.
 14. A lentiviral vector, comprising: (a) a henipavirus F protein molecule or biologically active portion thereof; and (b) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof, and wherein the binding domain binds CD4; and (c) a cargo comprising nucleic acid encoding a chimeric antigen receptor (CAR), wherein the CAR comprises (i) an extracellular antigen binding domain that binds CD19, (ii) a transmembrane domain and (iii) an intracellular signaling region comprising a CD3zeta signaling domain. 15-16. (canceled)
 17. A lentiviral vector, comprising: (a) a henipavirus F protein molecule or biologically active portion thereof; and (b) a targeted envelope protein comprising (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain, wherein the binding domain is attached to the C-terminus of the G protein or the biologically active portion thereof, and wherein the binding domain binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2 and TM4SF5. 18-19. (canceled)
 20. The lentiviral vector of claim 14, wherein the binding domain is attached to the G protein via a linker.
 21. The targeted lipid particle of claim 10, wherein the binding domain is a single domain antibody or is a single chain variable fragment (scFv). 22-23. (canceled)
 24. The targeted lipid particle of claim 1, wherein the G protein or the biologically active portion thereof is a wild-type Nipah virus G (NiV-G) protein or a Hendra virus G protein, or is a functionally active variant or biologically active portion thereof. 25-33. (canceled)
 34. The targeted lipid particle of claim 1, wherein the mutant NiV-G protein or the biologically active portion has the amino acid sequence set forth in SEQ ID NO: 16 or an amino acid sequence having at or about 80% sequence identity to SEQ ID NO:16.
 35. The targeted lipid particle of claim 1, wherein the F protein or the biologically active portion thereof is a wild-type Nipah virus F (NiV-F) protein or a Hendra virus F protein or is a functionally active variant or biologically active portion thereof. 36-39. (canceled)
 40. The targeted lipid particle of claim 1, wherein the NiV-F protein is a biologically active portion thereof that has a 22 amino acid truncation at or near the C-terminus of the wild-type NiV-F protein (SEQ ID NO:2).
 41. The targeted lipid particle of claim 1, wherein the NiV-F protein or the biologically active portion has the sequence set forth in SEQ ID NO:23 or an amino acid sequence that is encoded by a sequence of nucleotides encoding a sequence having at or about 80% sequence identity to SEQ ID NO:23.
 42. The targeted lipid particle of claim 1, wherein the F protein comprises the sequence set forth in SEQ ID NO:23 and the G protein comprises the sequence set forth in SEQ ID NO:16. 43-48. (canceled)
 49. The targeted lipid particle of claim 1, wherein the lipid particle further comprises an exogenous agent. 50-54. (canceled)
 55. The targeted lipid particle of claim 10, wherein the membrane protein is a chimeric antigen receptor (CAR).
 56. (canceled)
 57. The targeted lipid particle of claim 10, wherein the exogenous agent is a nucleic acid comprising a payload gene for correcting a genetic deficiency.
 58. A polynucleotide comprising a nucleic acid sequence encoding: (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a single domain antibody (sdAb) variable domain, wherein the sdAb variable domain is attached to the C-terminus of the G protein or the biologically active portion thereof; or (i) a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and (ii) a binding domain that binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, TM4SF5, CD4, CD8, and low density lipoprotein receptor (LDL-R). 59-90. (canceled)
 91. A vector comprising the polynucleotide of claim
 58. 92. (canceled)
 93. A plasmid comprising the polynucleotide of claim
 58. 94. (canceled)
 95. A cell comprising the vector of claim
 91. 96. A method of making a targeted lipid particle comprising a henipavirus F protein molecule or biologically active portion thereof and a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain, the method comprising: a) providing a cell that comprises a nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and a nucleic acid encoding a targeted envelope protein, the targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain; b) culturing the cell under conditions that allow for production of a targeted lipid particle, and c) separating, enriching, or purifying the targeted lipid particle from the cell, thereby making the targeted lipid particle.
 97. A method of making a pseudotyped lentiviral vector, the method comprising: a) providing a producer cell that comprises a lentiviral viral nucleic acid(s), a nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof, and a nucleic acid encoding a targeted envelope protein, said targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody; b) culturing the cell under conditions that allow for production of the lentiviral vector, and c) separating, enriching, or purifying the lentiviral vector from the cell, thereby making the pseudotyped lentiviral vector.
 98. A method of making a targeted lipid particle comprising a henipavirus F protein molecule or biologically active portion thereof and a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a binding domain, the method comprising: a) providing a cell that comprises a nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and a nucleic acid encoding a targeted envelope protein, the targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and binding domain, wherein the binding domain: (i) binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, and TM4SF5; (ii) binds a cell surface molecule selected from the group consisting of CD4 or CD8; or (iii) binds a cell surface molecule that is low density lipoprotein receptor (LDL-R); b) culturing the cell under conditions that allow for production of a targeted lipid particle, and c) separating, enriching, or purifying the targeted lipid particle from the cell, thereby making the targeted lipid particle, wherein the targeted lipid particle is a pseudotyped lentiviral vector. 99-105. (canceled)
 106. A producer cell comprising the polynucleotide of claim
 58. 107. The producer cell of claim 106, further comprising nucleic acid encoding a henipavirus F protein or a biologically active portion thereof.
 108. (canceled)
 109. A producer cell comprising (i) a viral nucleic acid(s) and (ii) nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and (iii) a nucleic acid encoding a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a single domain antibody (sdAb) variable domain. 110-113. (canceled)
 114. A producer cell comprising (i) a viral nucleic acid(s) and (ii) nucleic acid encoding a henipavirus F protein molecule or biologically active portion thereof and (iii) a nucleic acid encoding a targeted envelope protein comprising a henipavirus envelope attachment glycoprotein G (G protein) or a biologically active portion thereof and a binding domain, wherein the binding domain: (i) binds a cell surface molecule selected from the group consisting of ASGR1, ASGR2, and TM4SF5; (ii) binds a cell surface molecule selected from the group consisting of CD4 or CD8; or (iii) binds a cell surface molecule that is low density lipoprotein receptor (LDL-R). 115-123. (canceled)
 124. A targeted lipid particle produced by the method of claim
 96. 125-126. (canceled)
 127. A composition comprising a plurality of targeted lipid particles of claim
 1. 128-129. (canceled)
 130. A method of transducing a cell comprising transducing a cell with a lentiviral vector of claim
 13. 131. (canceled)
 132. A method of delivering an exogenous agent to a subject, the method comprising administering to the subject the targeted lipid particle of claim 49, wherein the targeted lipid particle comprises the exogenous agent.
 133. A method of delivering an exogenous agent to a subject, the method comprising administering to the subject the composition of claim 127, wherein targeted lipid particles of the plurality comprise the exogenous agent.
 134. A method of delivering a chimeric antigen receptor (CAR) to a cell, comprising contacting a cell with the lentiviral vector of claim 14, wherein the lentiviral vector comprises a nucleic acid encoding the CAR.
 135. A method of delivering a chimeric antigen receptor (CAR) to a cell, comprising contacting a cell with the composition of claim 127 wherein targeted lipid particles of the plurality comprise a nucleic acid encoding the CAR.
 136. A method of delivering an exogenous agent to a hepatocyte, comprising contacting a cell with the lentiviral vector of claim
 17. 137. A method of delivering an exogenous agent to a hepatocyte, comprising contacting a cell with the composition of claim 127, wherein targeted lipid particles of the plurality comprise an exogenous agent for delivery to the hepatocyte.
 138. (canceled)
 139. A method of treating a disease or disorder in a subject, the method comprising administering to the subject the composition of claim
 127. 140. A method of fusing a mammalian cell to a targeted lipid particle, the method comprising administering to the subject the composition of claim
 127. 141. (canceled) 